Methods to Identify Synthetic and Natural RNA Elements that Enhance Protein Translation

ABSTRACT

The present invention provides reagents and methods for identifying translation enhancing elements, as well as isolated translation enhancing elements and their use in protein expression reagents and methods.

CROSS-REFERENCE

This application claims priority to U.S. Provisional Patent Application Ser. No. 61/365,133 filed Jul. 16, 2010, incorporated by reference herein in its entirety.

STATEMENT OF U.S. GOVERNMENT INTEREST

This work was funded in part by NIH Eureka Award GM085530. The U.S. government has certain rights in the invention.

BACKGROUND

Ribosomal initiation constitutes a critical step in the protein translation process, allowing the ribosome to locate the correct AUG start site in the RNA message and initiate the transfer of genetic information from RNA into proteins via the genetic code. In eukaryotes, recruitment of the 40S ribosomal subunit to the RNA message occurs by recognition of a 7-methylguanosine cap located at the 5′ end of the mRNA strand. Ribosomal recruitment can also occur by a less common cap-independent mechanism, an example of which is the internal ribosomal entry site (IRES). In many cases, the recruitment site is located some distance upstream of the initiation codon, which poses the question of how the ribosome is able to bypass the intervening sequence. While linear scanning is the dominant model used to explain this process, emerging evidence suggests that transient mRNA-rRNA base pairing may play an important role in the initiation of certain mRNAs. This possibility, and the fact that the genome is routinely and pervasively transcribed into RNA, raise many interesting questions about the role of RNA inside cells and the potential for many unknown protein coding regions.

Discovering translation initiation elements (TIEs), also known as translation enhancing elements (TEEs) in human and other higher order genomes is a challenging problem as computational methods are unable to locate these sequences at the DNA level. This limitation has created a pressing need for new functional tools that can be used to identify and map these sequences in known genomes.

SUMMARY OF THE INVENTION

In a first aspect, the present invention provides nucleic acid libraries comprising a plurality of linear recombinant double stranded DNA constructs, wherein each double stranded DNA construct comprises

(a) a promoter;

(b) a heterologous coding region downstream from the promoter, wherein the coding region encodes a detectable polypeptide;

(c) a heterologous cross-linking region downstream of the coding region;

(d) a heterologous polynucleotide sequence of between 20-500 base pairs in length located downstream of the promoter and upstream of the coding region; and

(e) a first PCR primer binding site and a second PCR primer binding site, wherein the first PCR primer binding site is upstream of the polynucleotide sequence and the second PCR primer site is downstream of the polynucleotide sequence;

wherein at least 10¹³ different polynucleotide sequences are represented in the plurality of double stranded nucleic acid constructs, and wherein the first PCR primer and the second PCR primer are the same for each construct in the plurality of double stranded nucleic acid constructs.

In a second aspect, the present invention provides mRNA pools, comprising mRNA transcripts resulting from transcription of the nucleic acid libraries of the first aspect of the invention.

In a third aspect, the present invention provides methods for identifying translational enhancing elements (TEEs), comprising

(a) contacting the nucleic acid library of the first aspect of the invention with reagents for RNA transcription under conditions to promote transcription of RNA from the double stranded nucleic acid constructs, resulting in an RNA expression product;

(b) contacting the RNA expression product with reagents for ligating a linker containing a puromycin residue to the 3′ end of the RNA expression product, resulting in a labeled RNA expression product;

(c) contacting the labeled RNA expression product with reagents for protein expression under conditions to promote protein translation from the labeled RNA expression product, resulting in a RNA-polypeptide fusion product;

(d) isolating RNA-polypeptide fusion products;

(e) converting the isolated RNA-polypeptide fusion products to cDNA by reverse transcription-PCR using a primer to the 3′ end of the isolated RNA-polypeptide fusion products;

(f) amplifying the cDNA by PCR using primers to the 5′ and 3′ end of the cDNA; and

(g) repeating steps (a)-(f) a desired number of times, wherein the amplified polynucleotide sequence fragments comprise TEEs.

In a fourth aspect, the present invention provides isolated polynucleotides, comprising a nucleic acid sequence according to any one of SEQ ID NOS: 1-5 and 7-645. These polynucleotides have been identified as TEEs using the methods of the present invention.

In a fifth aspect, the present invention provides expression vectors comprising

(a) a promoter;

(b) a heterologous TEE downstream of the promoter, where the TEE comprises a polynucleotide according to the fourth aspect of the invention; and

(c) a cloning site suitable for cloning of an protein-encoding nucleic acid of interest located upstream of the TEE, and downstream of the promoter.

In a sixth aspect, the present invention provides recombinant host cells comprising the expression vector of the fifth aspect of the invention.

In a seventh aspect, the present invention provides methods for protein expression, comprising contacting an expression vector of the fifth aspect of the invention with reagents and under conditions suitable for promoting expression of a polypeptide cloned into the cloning site.

DESCRIPTION OF THE FIGURES

FIG. 1. In vitro selection and characterization of RNA elements that mediate cap-independent. (A) Human genomic DNA fragments were inserted into a DNA cassette containing all of the sequence information necessary to perform an mRNA display selection. For each selection round, the dsDNA pool was in vitro transcribed into ssRNA, conjugated to a DNA-puromycin linker, and translated in vitro. Uncapped mRNA sequences that initiate translation of an intact ORF become covalently linked to a His-6 protein affinity tag encoded in the RNA message. Functional molecules are recovered, reverse transcribed, and amplified by PCR to generate the input for the next round of selection. (B) Generation of RNA-protein fusion molecule by the natural peptidyl transferase activity of the ribosome, which catalyzes the formation of a non-hydrolyzable amide bond between puromycin and the polypeptide chain. (C) The selection progress was monitored by measuring the fraction of S³⁵-labeled mRNA-peptide fusions that bound to an oligo-dT column and a Ni-NTA affinity column. Chromosomal distribution of in vitro selected sequences with 100% sequence similarity to the human reference genome (D) and their evolutionary conservation compared to the starting library (round 0) (E). (F) The distribution of individual repeat families in the starting library, random genomic sequences, and the in vitro selected sequences.

FIG. 2. Functional analysis of top nine sequences in human cells. (A) Schematic diagram showing the individual steps of a coupled transcription-translation assay for cytoplasmic RNA expression and analysis. A luciferase reporter plasmid carrying an insert and a promoter sequence specific to the vaccinia virus is transfected into HeLa cells that are immediately infected with vaccinia virus. Virus-infected cells synthesize a vaccinia RNA polymerase that enables cytoplasmic transcription of the reporter plasmid into RNA. The mRNA transcripts are translated by endogenous ribosomes and the cells are assayed for bioluminescence activity after 6 hours of infection. The translation efficiency of the top nine sequences identified in the cell-based screen in (B) HeLa cells and (C) in vitro in HeLa cell lysate.

FIG. 3. Functional analysis of the top nine sequences in the hairpin plasmid. (A) The sequences were inserted into a firefly reporter plasmid (F-luc-hp) containing a stable stem-loop structure. (B) The translation efficiency of the controls with no insert in vitro and in cell-based assays with and without the stable stem-loop structure. (C) The translation efficiency of the top nine sequences in vitro relative to the no insert control.

-   -   (D) The translation efficiency of the top nine sequences in HeLa         cells relative to the no insert control after normalization for         mRNA (E) No infection assay in HeLa cells demonstrating that         HGL6.877, HGL6.1033, and HGL6.733 have weak promoter activity         that is specific to vaccinia virus infection. No activity is         observed for these sequences in the absence of the vaccinia         virus (inset).

FIG. 4. Translation initiation efficiency of AUG triplet patterns. (A) In vitro translation efficiency of selected sequences with in-frame and out-of-frame AUG triplets. (B) Gel image illustrating start site usage of sequences in rabbit and human cell lysate. (C) In vitro translation efficiency of HGL6.877 and an unselected sequence (HGL0.53) with various combinations of AUG triplets.

DETAILED DESCRIPTION OF THE INVENTION

In a first aspect, the present invention provides nucleic acid libraries comprising a plurality of linear recombinant double stranded DNA constructs, wherein each double stranded DNA construct comprises

(a) a promoter;

(b) a heterologous coding region downstream from the promoter, wherein the coding region encodes a detectable polypeptide;

(c) a heterologous cross-linking region downstream of the coding region;

(d) a heterologous polynucleotide sequence of between 20-500 base pairs in length located downstream of the promoter and upstream of the coding region; and

(e) a first PCR primer binding site and a second PCR primer binding site, wherein the first PCR primer binding site is upstream of the polynucleotide sequence and the second PCR primer site is downstream of the polynucleotide sequence;

wherein at least 10¹³ different polynucleotide sequences are represented in the plurality of double stranded nucleic acid constructs, and wherein the first PCR primer and the second PCR primer are the same for each construct in the plurality of double stranded nucleic acid constructs.

The nucleic acid libraries according to the present invention can be used, for example, in the methods of the invention for performing in vitro selection for the isolation of RNA elements (TEEs, including internal ribosome entry sites (IRESs)) that can mediate cap-independent protein translation. The libraries comprise a series of linear constructs, which, when used in in vitro selection methods as described herein, permit use of a library diversity of at least 10¹³ different polynucleotide sequences. As described in detail below, the inventors have used the libraries of the present invention to identify a large number of novel TEEs, including a number of IRESs. As used herein, a “library” is a collection of linear double stranded nucleic acid constructs.

As used herein, “heterologous” means that none of the promoter, coding region, genomic fragment, and cross-linking region are normally associated with each other (ie: they are not part of the same gene in vivo), but are recombinantly combined in the construct.

As used herein, a “promoter” is any DNA sequence that can be used to help drive RNA expression of a DNA sequence downstream of the promoter. Suitable promoters include, but are not limited to, the T7 promoter, SP6 promoter, CMV promoter, and vaccinia virus synthetic-late promoter. As will be understood by those of skill in the art, a given double stranded DNA construct may contain more than one promoter, as appropriate for a given proposed use.

As used herein, a “coding region” is any DNA sequence encoding a polypeptide product. As used herein, a “detectable polypeptide” is any polypeptide whose expression can be detected, including but not limited to a fluorescent polypeptide (GFP, BFP, etc.), a member of a binding pair, an affinity tag, etc. The ability to detect the polypeptide greatly facilitates the methods of the invention. Non-limiting examples of such detectable polypeptides include affinity tags, protein DX (Smith et al. (2007) PLoS ONE 2, e467), maltose-binding protein (MBP), streptavadin, glutathionine S-transferase (GST), flagellar protein FlaG (FLAG affinity tag), and myelocytomatosis and viral oncogene homologs (Myc affinity tag).

As used herein, a “cross linking region” is any nucleic acid sequence that can be expressed as RNA, where the expressed RNA can serve as a site for ligation/binding to a linker to form a stable complex between mRNA-ribosome-protein. In a preferred embodiment, expressed RNA from the cross-linking region can serve as a site for ligation to a linker containing a 3′-puromycin residue. In a non-limiting embodiment, the expressed RNA from the cross-linking region can serve as a site for photo-ligation of a psoralen-DNA-puromycin linker (5′-psoralen-(oligonucleotide complementary to linker)-(PEG₉)₂-A₁₅-ACC-puromycin). In a preferred embodiment, the linker is a DNA linker, and the mRNA expressed from the cross linking region is complementary to the DNA linker sequence to be used.

The polynucleotide sequence can be any suitable length, such as between 20-1000 base pairs. In a preferred embodiment, the polynucleotide sequence is between 20-500 base pairs, and may comprise genomic fragments, such as a representation of an entire or partial genome from an organism of interest, or may comprise synthetic sequences. In embodiments where genomic fragments are used, the genomic fragments may be generated by any appropriate means, including restriction enzyme digestion, shearing, polynucleotide synthesis, etc. Genomic fragments from any suitable organism of interest may be used, including but not limited to human, mammal, fish, reptile, plant, yeast, insect, prokaryotic, bacterial (E. coli, etc.), viral, fungal, and pathogenic organism genomic fragments. In another preferred embodiment, such genomic fragments are obtained from plurality of individual organisms of a single species; in a further embodiment, the plurality of individual organisms of a single species differ in ancestry, age, gender, and/or other characteristics.

The primer binding sites provide regions of known sequence around the polynucleotide sequence of unknown sequence to be tested for TEE activity. Additionally the primer binding sites provide a way to amplify only the polynucleotide sequence back out of the construct as desired. As will be understood by those of skill in the art, any suitable sequence can be used as a primer binding site so long as it can be used to bind a primer of interest. The primer binding site may be immediately adjacent to the polynucleotide sequence, or there may be additional nucleotides present between the primer binding site and the polynucleotide sequence as deemed appropriate for a given purpose.

As used herein, “at least 10¹³ different polynucleotide sequences are represented in the plurality of double stranded nucleic acid constructs” means that the library, in its entirety, contains at least 10¹³ different polynucleotide sequences that can be tested for TEE activity, while each different double stranded nucleic acid construct contains only a single polynucleotide sequence. In various embodiments, at least 10¹⁴ different polynucleotide sequences or at least 10¹⁵ different polynucleotide sequences are represented in the plurality of double stranded nucleic acid constructs.

It will be understood by those of skill in the art that the constructs of the invention may comprise further nucleotide elements as appropriate for a given intended use. In one preferred embodiment, the double stranded nucleic acid constructs further comprise one or more unique restriction sites upstream of the polynucleotide sequence and downstream of the promoter, and one or more unique restriction sites downstream of the polynucleotide sequence. This embodiment provides a further means by which to isolate polynucleotide sequences of interest from the constructs. In a further embodiment, the constructs do not include sequences encoding a 3′ poly(A) tail, or sequences that promote formation of a 5′ cap on the resulting transcript.

In another preferred embodiment, the second (3′) primer binding site is immediately upstream of the coding region in the double stranded nucleic acid construct. In this embodiment, the 3′ primer binding site abuts the coding region when the polynucleotide sequence is upstream of the promoter.

In a second aspect, the present invention provides an mRNA pool resulting from transcription of the library of any embodiment of the first aspect of the invention. Such mRNA pools can be used, for example, in the methods of the invention below. Any suitable technique for RNA transcription can be used. In one non-limiting embodiment, the double stranded DNA constructs each comprise a T7 RNA polymerase promoter, and the library is transcribed in vitro using T7 RNA polymerase, using standard techniques. It will be clear to those of skill in the art how to optimize transcription conditions in terms of buffers, nucleotides, salt conditions, etc., based on the general knowledge of in vitro transcription techniques in the art. The resulting mRNA pools will comprise single stranded RNA from all/almost all the double stranded DNA constructs in the library. In a further embodiment, the transcripts in the pooled mRNA comprise a DNA linker, containing a 3′ puromycin residue, ligated at the 3′ end of the transcript. In a further aspect, the invention provides pooled mRNA-peptide fusion molecules resulting from in vitro translation of the pooled mRNA. Methods for in vitro translation of RNA transcripts are well known to those of skill in the art. In one non-limiting embodiment, the methods comprise incubating the pooled mRNA with rabbit reticulocyte lysate and ³⁵S-methionine for a suitable time. The method may further comprise incubating the mixture overnight in the presence of suitable amounts of KCl and MgCl₂ to promote fusion formation. When the pool of RNA is translated in vitro, transcripts that contain a TEE (such as an IRES) in their 5′ UTR would initiate translation and produce an mRNA-peptide fusion molecule; thus, modifying TEE-containing RNAs with a selectable tag. The chemical bond forming step of mRNA display is due to the natural peptidyl transferase activity of the ribosome, which catalyzes the formation of a non-hydrolyzable amide bond between puromycin and the polypeptide chain (FIG. 1B). mRNA-peptide fusion molecules can be isolated by affinity purification, reverse-transcribed, and amplified to regenerate the pool of DNA for another selection cycle.

In a third aspect, the present invention provides in vitro methods for identifying translational enhancing elements (TEEs), comprising

(a) contacting the nucleic acid library of any embodiment or combination of embodiments of the first aspect of the invention with reagents for RNA transcription under conditions to promote transcription of RNA from the double stranded nucleic acid constructs, resulting in an RNA expression product;

(b) contacting the RNA expression product with reagents for ligating a linker containing a puromycin residue to the 3′ end of the RNA expression product, resulting in a labeled RNA expression product;

(c) contacting the labeled RNA expression product with reagents for protein expression under conditions to promote protein translation from the labeled RNA expression product, resulting in a RNA-polypeptide fusion product;

(d) isolating RNA-polypeptide fusion products;

(e) converting the isolated RNA-polypeptide fusion products to cDNA by reverse transcription-PCR using a primer to the 3′ end of the isolated RNA-polypeptide fusion products;

(f) amplifying the cDNA by PCR using primers to the 5′ and 3′ end of the cDNA; and

(g) repeating steps (a)-(f) a desired number of times, wherein the amplified polynucleotide sequence fragments comprise TEEs.

The methods of this aspect of the present invention serve to isolate RNA elements that could mediate cap-independent translation (ie: TEEs, including but not limited to IREs). The mechanism-based approach of mRNA display provides an efficient method to systematically and comprehensively survey nucleic acid sequences for all of the possible RNA elements that could initiate translation of uncapped mRNA transcripts. Since IRESs function by a cap-independent mechanism, this selection serves to identify IRESs as well as TEEs that promote cap-independent translation but do not initiate internally. All terms used in this third aspect have the same meaning as used elsewhere herein; similarly, all embodiments of the nucleic acid libraries and components thereof that are disclosed above, and combinations thereof, can be used in the methods of the invention. Thus, for example, each double stranded DNA construct comprises

(a) a promoter;

(b) a heterologous coding region downstream from the promoter, wherein the coding region encodes a detectable polypeptide;

(c) a heterologous cross-linking region downstream of the coding region;

(d) a heterologous polynucleotide sequence of between 20-1000 base pairs in length located downstream of the promoter and upstream of the coding region; and

(e) a first PCR primer binding site and a second PCR primer binding site, wherein the first PCR primer binding site is upstream of the polynucleotide sequence and the second PCR primer site is downstream of the polynucleotide sequence. In one non-limiting embodiment, the heterologous polynucleotide sequences are randomly digested fragments (in various non-limiting embodiments, ranging between 20-1000 nts, 20-750 nts, 20-500 nts; or about 150 nts) of total human DNA. Since the heterologous polynucleotide sequence is located downstream of the promoter and upstream of the coding region.

In the method, step (f) amplifying the cDNA by PCR using primers to the 5′ and 3′ end of the cDNA serves to add sequence information that was lost in steps (a) and (e). In one embodiment, primers to add a promoter (such as a T7 promoter) to the 5′ end and the cross-linking region (such as a photo-crosslinking) site (3′ end) back onto the DNA library are after each round of selection. The sequence of these PCR primers may vary depending on how each library is constructed. The result of this PCR is the fully constructed double stranded nucleic acid construct, which can be used to repeat steps (a)-(f) as desired.

Contacting the RNA expression product with reagents for ligating a linker containing a puromycin residue to the 3′ end of the RNA expression product, resulting in a labeled RNA expression product, can be carried out via any suitable method, including photo-crosslinking or Moore-Sharp splint-directed ligation.

Any suitable linker may be used. In a preferred embodiment the linker comprises a DNA linker complementary to the transcribed single stranded RNA. The DNA linker may comprise any suitable modifications, including but not limited non-natural residues and pegylation, as can be used in mRNA display.

In one preferred embodiment, the polynucleotide sequences in the library comprise genomic fragments; in a further preferred embodiment the starting pool of constructs used in the methods contains at least a 5×-1000× coverage of the genome of interest.

General conditions for in vitro transcription and translation, PCR, reverse transcription, and mRNA display techniques (including contacting an RNA expression product with reagents for ligating a linker containing a puromycin residue to the 3′ end of the RNA expression product), are well known to those of skill in the art. Exemplary such conditions are described above and in the examples that follow. To favor the selection of RNA elements that enhance ribosomal recruitment via a cap-independent mechanism, the pool of RNA transcripts is preferably devoid of a 5′ cap and 3′ poly(A) tail. As will be apparent to those of skill in the art, this can be accomplished, for example, by not including polyT sequences in the DNA template (to avoid poly(A) tail production) and by not providing capping enzymes required for 5′ cap production.

When the pool of RNA is translated in vitro, transcripts that contain a TEE in their 5′ UTR initiate translation and produce an mRNA-peptide fusion molecule; thus, modifying TEE-containing RNAs with a selectable tag. The chemical bond forming step of mRNA display is due to the natural peptidyl transferase activity of the ribosome, which catalyzes the formation of a non-hydrolyzable amide bond between puromycin and the polypeptide chain (FIG. 1B). mRNA-peptide fusion molecules can then be isolated by affinity purification, reverse-transcribed, and amplified to regenerate the pool of DNA for another selection cycle.

In one non-limiting embodiment, for each round of selection, the dsDNA library was transcribed with an RNA polymerase suitable for the promoter being used, photo-ligated to a psoralen-DNA-puromycin linker (5′-psoralen-oligonucleotide complementary to linker)-(PEG₉)₂-A₁₅-ACC-puromycin), and translated in vitro by incubating the library with rabbit reticulocyte lysate and ³⁵S-methionine under suitable conditions. mRNA-peptide fusion molecules are reverse transcribed, and can be purified by any suitable means, including but not limited to a two-step procedure on oligo (dT)-cellulose beads (NEB) and Ni-NTA agarose affinity resin (Qiagen). Functional TEEs are recovered by any suitable technique, including but not limited to eluting the column with imidazole, dialyzing the sample into water, and amplifying the cDNA by PCR. The selection progress can be monitored using any suitable technique, including but not limited to determining the fraction of S³⁵-labeled mRNA-peptide fusions that remained on the oligo (dT)/Ni-NTA affinity columns. After a desired number of rounds of selection and amplification, the TEEs can be identified by any suitable means, including but not limited to cloning and sequencing of the amplified DNA constructs.

The selection process (steps (a)-(f)) can be carried out any suitable number of times deemed appropriate to identify TEEs, such as 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, or more times. In one preferred embodiment, at least three selection cycles are carried out, such that step (g) comprises repeating steps (a)-(f) at least two more times, and even more preferably at least 3, 4, 5, 6, 7, 8, 9, or more times.

In one embodiment, the method further comprises testing polynucleotide sequences identified as TEEs for TEE activity in vivo using, for example, the vaccinia system described herein. Any suitable system may be used. In one non-limiting embodiment, a plasmid-based reporter assay that allows coupled transcription and translation to occur in the cytoplasm of human cells was developed (FIG. 2A), to test sequences under conditions that are not subject to nuclear processing. This system is based on an EMCV-driven system that relies on vaccinia virus (VACV) to circumvent nuclear expression (25). TEE candidate sequences are cloned into a monocistronic firefly luciferase reporter plasmid (F-luc-mono) containing a VACV-specific promoter. Transfected HeLa cells are infected with VACV, and after a brief incubation, cells are lysed and assayed for luciferase activity. Plasmids carrying no-insert or a randomly chosen sequence from the starting pool provided a basal level of activity.

In a further embodiment, TEE candidate sequences are tested for the ability to initiate internal translation initiation. Any suitable assay for testing internal translation initiation can be used, including but not limited to those disclosed herein. In one non-limiting embodiment, TEE candidate sequences are inserted into a firefly reporter plasmid (F-luc-hp) containing a stable stem-loop structure (ΔG=−58 kcal/mol) to prevent ribosomal scanning (FIG. 3A) (26).

In a fourth aspect, the present invention provides isolated polynucleotides, comprising a nucleic acid sequence according to any one of SEQ ID NOS: 1-5 and 7-645. In another embodiment, the isolated polynucleotides comprise or consist of a sequence according to one or more of SEQ ID NO: 7-645, listed in Table 1. The isolated polynucleotides listed in the recited tables were all identified as TEEs by the methods of the invention; all are human genomic sequences, and thus can be used, for example, in designing expression vectors for improved translational efficiency of one or more proteins encoded by the vector. In various preferred embodiments, the isolated polynucleotides are between 13-180, 13-170, 13-160, 13-150, 13-140, 13-130, 13-120, 13-110, 13-100, 13-90, 13-80, 13-70, 13-60, 13-50, 13-40, 13-30, or 13-20 nucleotides in length. In a preferred embodiment, the isolated polynucleotides consist of the recited sequence. In a further embodiment, the isolated polynucleotides comprise the sequence of SEQ ID NO:4 (A/-)(A/G)ATC(A/G)(A/G)TAAA(T/C)G, wherein the isolated polynucleotides is between 13-200 nucleotides in length. SEQ ID NO:4 is a consensus sequence found within a number of the TEES (Clones 985 (SEQ ID NO:448), 1092 (SEQ ID NO:495), 1347 (SEQ ID NO:623), 906 (SEQ ID NO:408), 12 (SEQ ID NO:12), 1200 (SEQ ID NO:553), 958 (SEQ ID NO:434), 1011 (SEQ ID NO:458), 459 (SEQ ID NO:214) in Table 1) identified using the methods of the invention. In a preferred embodiment, the isolated polynucleotides comprise the sequence of SEQ ID NO:55′-AAATCAATAAATG-3′, which is a conserved sequence found in the top-performing TEEs as described in the examples that follow. In various preferred embodiments, the isolated polynucleotides are between 13-180, 13-170, 13-160, 13-150, 13-140, 13-130, 13-120, 13-110, 13-100, 13-90, 13-80, 13-70, 13-60, 13-50, 13-40, 13-30, or 13-20 nucleotides in length.

In one embodiment, the polynucleotide is selected from the group consisting of SEQ ID NO:583 (clone 1267), SEQ ID NO:397 (clone 877), SEQ ID NO:54 (clone 100), SEQ ID NO:401 (clone 884), SEQ ID NO:471 (clone 1033), SEQ ID NO:327 (clone 733), SEQ ID NO:398 (clone 878), SEQ ID NO:301 (clone 675), and SEQ ID NO:310 (clone 694). These sequences have been identified as IRESs using the methods disclosed herein. In a further embodiment, the present invention provides isolated polynucleotides comprising a nucleic acid sequence according to SEQ ID NO:1. This sequence represents a consensus sequence of a subset of 733 (SEQ ID NO:327), 877 (SEQ ID NO:397), 1033 (SEQ ID NO:471), and 1267 (SEQ ID NO:583), and thus is strongly correlated with activity. In further embodiments, the isolated polynucleotides comprise a nucleic acid sequence according to SEQ ID NO:2 or SEQ ID NO:3, which are longer portions of the consensus sequence between 733 (SEQ ID NO:327), 877 (SEQ ID NO:397), 1033 (SEQ ID NO:471), 1267 (SEQ ID NO:583.

SEQ ID NO: 1: 5′AT(C/G)GAAT(C/G)(G/A)AA(G/T)(A/G/C)GAATGGA(A/T) (A/T)(C/A/G)(A/G)AA(T/A)GGAAT(G/A)GAAT(T/G)(G/A)A ATGGAATGGAA(T/A)(T/G)GA(A/T)T(G/C)GAATG-3′ SEQ ID NO: 2: 5′-(

--)(

--)(

--)(

--)(

--) (

--)(

--)(

--)(

--)(

/--)(--/

) (-

)AT(C/G) GAAT(C/G)(G/A)AA(G/T)(A/G/C)GAATGGA(AT)(A/T) (C/A/G)(A/G)AA(T/A)GGAAT(G/A)GAAT(T/G)(G/A) AATGGAATGGAA(T/A)(T/G)GA(A/T)T(G/C)GAATG-3′ SEQ ID NO; 3 5′-(

--)(

--)(

--)(

--)(

--)(

--) (

--)(

--)(

--)(

--)(A/--)(A/--)(G/A/--) (C/T/--)(G/--)(G/--)(A/--)(A/--)(T/--)(T/C/--) (--/A/G)(--/A)AT(C/G) GAAT(C/G)(G/A)AA(G/T)(A/G/C)GAATGGA(AT)(A/T) (C/A/G)(A/G)AA(T/A)GGAAT(G/A)GAAT(T/G)(G/A) AATGGAATGGAA(T/A)(T/G)GA(A/T)T(G/C)GAATG-3′

In a fifth aspect, the present invention provides expression constructs comprising:

(a) a promoter;

(b) a heterologous translational initiation element (TEE) downstream of the promoter, where the TEE comprises or consists of a sequence according to any one of SEQ ID NO:1-5 and 7-645; and

(c) a polylinker suitable for cloning of an open reading frame of interest located upstream or downstream of the TEE, and downstream of the promoter.

In this aspect, the invention provides constructs comprising the TEEs of the invention that are positioned relative to the polylinker (ie: one or more unique restriction sites to facilitate cloning) to increase translational efficiency of any polynucleotide coding region cloned into the polylinker. In a preferred embodiment, the TEE is between 13-500 nucleotides in length; in a more preferred embodiment, between 13 and 200 nucleotides in length. In a preferred embodiment, the polylinker is located downstream of the TEE. Any suitable coding region for which an increase in translational efficiency is desired can be cloned into the vector. Thus, in a further embodiment, the construct comprises a polynucleotide coding region cloned into the polylinker. In a further preferred embodiment, the TEE comprises or consists of the sequence of any one or more of SEQ ID NOS:1-5, 448, 495, 623, 408, 12, 553, 434, 458, 214, 327, 397, 471, and 583. In a further preferred embodiment, the TEE comprises or consists of the sequence of any one or more of 583 (clone 1267), SEQ ID NO:397 (clone 877), SEQ ID NO:54 (clone 100), SEQ ID NO:401 (clone 884), SEQ ID NO:471 (clone 1033), SEQ ID NO:327 (clone 733), SEQ ID NO:398 (clone 878), SEQ ID NO:301 (clone 675), and SEQ ID NO:310 (clone 694). These sequences have been identified as IRESs using the methods disclosed herein. Suitable promoters include, but are not limited to, the T7 promoter, SP6 promoter, CMV promoter, and vaccinia virus synthetic-late promoter. The constructs in this aspect of the invention may be linear constructs, or may be part of an expression vector, such as a plasmid or viral-based expression vector as are known in the art. As will be apparent to those of skill in the art, the constructs may contain any other components as desired by a user, such as origins of replication, selection markers, etc.

In a sixth aspect, the present invention provides recombinant host cell comprising an expression vector of any embodiment or combination of embodiments of the fifth aspect of the invention. Such host cells can be used, for example, to prepare large amounts of the expression vector and to provide for expression of the encoded proteins in the host cells. Any suitable host cell may be used, including but not limited to bacterial and eukaryotic host cells, including but not limited to mammalian and human cells.

In a seventh aspect, the present invention provides methods for protein expression, comprising contacting an expression construct according to any embodiment or combination of embodiments of the fifth aspect of the invention, wherein the construct comprises a polynucleotide coding region cloned into the polylinker, with reagents and under conditions suitable for promoting expression of the polypeptide encoded by the polynucleotide coding region. It is within the level of skill in the art to choose appropriate reagents and conditions for RNA expression from the expression construct, followed by translation of the encoded polypeptide. Exemplary reagents and conditions are described in the examples that follow. The methods of this aspect of the invention may be carried out in vitro or in vivo.

Unless clearly dictated otherwise by the context, all embodiments of any aspect of the invention may be combined with other embodiments of the same and different aspects.

Example 1 Genome-Wide Identification of Human Cap-Independent Translation Initiation Elements

Internal ribosomal entry sites (IRESs) are RNA elements located in the untranslated region of mRNA transcripts that initiate protein synthesis independent of the canonical 5′ cap. To date, only a handful of IRESs have been identified in higher order genomes. Here, we have applied a mechanism-based approach to search the entire human genome for RNA sequences with IRES activity. Starting from a library of >10¹³ human RNA fragments, we performed iterative cycles of mRNA display to capture leader sequences that mediate cap-independent translation. The selected sequences are distributed throughout the genome, and often occur in repetitive regions with high conservation to mammals. We observed strong cis-regulatory activity for more than 200 sequences tested in a monocistronic translation-enhancing assay. The most active sequences function as potent IRESs in vitro and in human cells. These results demonstrate the power of mRNA display as a genome-wide tool for identifying functional IRESs.

Initiation is a critical step in protein translation, allowing the ribosome to locate the translation start site in the RNA message and initiate the transfer of genetic information from RNA into protein via the genetic code. In eukaryotes, the 43S ribosomal pre-initiation complex (PIC) is recruited to the RNA message by recognition of the eIF4F cap-binding complex bound to a 7-methylguanosine cap located at the 5′ end of the mRNA strand (1, 2). A subset of leader sequences known as internal ribosomal entry sites (IRESs) can bypass the 5′ cap structure by recruiting the ribosome to internal positions in the 5′ untranslated region (5′ UTR) (3-7). IRESs play an important role in gene regulation by allowing essential proteins to be synthesized when normal cap-dependent translation is compromised (8). This can occur during regular cellular processes like mitosis and apoptosis (9, 10), as well as during hypoxia (11), viral infection (12), or during states of cellular dysregulation (13).

Ribosomal profiling, a technique that combines polysome fractioning with DNA microarrays, has been employed to profile cellular translation under conditions that impede normal cap-dependent translation (14). Data from these studies suggest that the human genome likely contains many more IRESs than previously thought; however, only a few human IRESs have been characterized in detail. These studies further suggest that cellular systems may possess mechanisms to support the coordinated regulation of specific IRES subtypes, as different physiological conditions gave rise to different IRES subsets. Despite a wealth of useful information gained by ribosomal profiling, this approach suffers from limited resolution and sequence accuracy, as well as an inability to distinguish stalled ribosomes from actively translating ribosomes. While continued technological advancement could circumvent some of these problems, thorough investigation of the human genome would require exhaustive sampling of countless conditions and cell types. This limitation has created a need for new molecular tools that can be used to identify human IRESs on a genome-wide scale (15).

To identify IRESs encoded in the human genome, we devised an in vitro selection strategy for the isolation of RNA elements that could mediate cap-independent translation. We reasoned that the mechanism-based approach of mRNA display provided an efficient method to systematically and comprehensively survey the entire human genome for all of the possible RNA elements that could initiate translation of uncapped mRNA transcripts (16). Since IRESs function by a cap-independent mechanism, it was hypothesized that this selection would lead to the discovery of human IRESs as well as human translation enhancing elements that promote cap-independent translation but do not initiate internally. In this scheme (FIG. 1A), a genomic library composed of randomly digested fragments (˜150 nts) of total human DNA was inserted into the 5′ UTR of a DNA cassette containing an open reading frame (ORF) encoding a peptide affinity tag. The library also contained all of the genetic information required for mRNA display. The library was converted to single-stranded RNA by in vitro transcription and photo-ligated at the 3′ end to a DNA linker containing a 3′ puromycin residue. To favor the selection of RNA elements that enhance ribosomal recruitment via a cap-independent mechanism, the pool of RNA transcripts was deprived of a 5′ cap and 3′ poly(A) tail. When the pool of RNA is translated in vitro, transcripts that contain an IRES in their 5′ UTR would initiate translation and produce an mRNA-peptide fusion molecule; thus, modifying IRES-containing RNAs with a selectable tag. The chemical bond forming step of mRNA display is due to the natural peptidyl transferase activity of the ribosome, which catalyzes the formation of a non-hydrolyzable amide bond between puromycin and the polypeptide chain (FIG. 1B) (17). mRNA-peptide fusion molecules could then be isolated by affinity purification, reverse-transcribed, and amplified to regenerate the pool of DNA for another selection cycle.

We started the selection with an RNA-DNA-puromycin library that contained >10¹³ sequences, which provided 100-1000-fold coverage of the human genome. We translated the library for 1 hour at 30° C. in nuclease treated reticulocyte lysate and fusion formation was promoted by incubating the mixture overnight at −20° C. in the presence of 600 mM KCl and 75 mM MgCl₂. mRNA-peptide fusions were isolated from the crude lysate by affinity purification on an oligo-(dT) resin, and the elution fractions were applied to Ni-NTA agarose beads. The Ni-NTA beads were thoroughly washed to remove RNA sequences that did not form mRNA-peptide fusions or did not initiate in the correct reading frame. mRNA-peptide fusions that remained bound to the column were selectively eluted with imidazole, exchanged into buffer, reverse-transcribed, and amplified by PCR to reinitiate the selection cycle described above. We monitored the selection progress by following the proportion of S³⁵-labeled mRNA-peptide fusions that remained in the pool after purification. The abundance of mRNA-peptide fusions increased up to round 5 and plateaued in round 6, indicating that the library became dominated by RNA elements that could enhance cap-independent translation (FIG. 1C).

We cloned and sequenced 712 members from round 6. Of these, 639 were non-redundant, indicating that the library contained significant sequence diversity even after six rounds of mRNA display (Table S1). Each non-redundant sequence was aligned to the human reference genome (hg18) using the UCSC BLAT web-tool (18). A subset of 229 sequences showed 100% identity to 1814 genomic locations. These sites are distributed across all 24 human chromosomes with ˜34% occurring in the intronic regions of known genes (FIG. 1D). The remaining 410 sequences have high homology (85-99% identity) to genomic sites, but contain small degrees of sequence variation that include single nucleotide polymorphisms in addition to small and large insertions and deletions. This level of variation is expected for individuals in a population (19), and it is known that gene regulatory sequences can differ between individual genomes (20). Since we could not distinguish between mutations that arose during the selection and those that occur naturally, we focused the remainder of our study on the set of 229 perfectly matched sequences.

We examined their evolutionary conservation using the 44-species UCSC alignments (FIG. 1E) (18). Of the 229 sequences, 82.5% are conserved in the chimpanzee genome (Pan troglodytes) and 43.2% are conserved in the genomes of other placental mammals (i.e., dogs, horses, and mice). The degree of sequence similarity ranged from 97-100% for chimpanzee and 96-100% for placental mammals. Sometimes significant sequence similarities (E-value<9e-13) were also observed in lower vertebrate genomes. For example, HGL6.634 homologs are found in lizards (Anolis carolinensis) and fish (Xenopus tropicalis and Gasterosteus aculeatus). This sequence overlaps the intron-exon junction for a chromatin modification-related protein. Similarly, HGL6.1305 shows high sequence similarity to the platypus and opossum genomes. This sequence is located in the intron of a neuronal PAS domain protein—a transcription factor expressed primarily in mammalian forebrains.

Because many of the perfectly matched sequences mapped to multiple genomic locations, we compared the distribution of repetitive elements found in the starting library to that of all round 6 sequences. The distribution of repetitive elements in the starting library is similar to the distribution obtained by random computational sampling (FIG. 1F). This is expected because our starting library contained an unbiased representation of the human genome (21-23). In contrast, round 6 was enriched in sequences that align to repetitive regions of the human genome. Of the 639 non-redundant sequences, most align to regions of LINE-1 (L1) retrotransposons and satellite DNA (25% and 45%, respectively). This distribution is comparable to what we observed for the set of 229 perfectly matched sequences with the difference that L1 elements are overrepresented at the expense of satellite DNA. This difference is not unexpected, as satellite DNA is known to contain large numbers of point mutations, which preclude their ability to map with 100% identity to the human reference genome (23).

We chose the set of 229 perfectly matched sequences and a set of 15 high homology sequences for functional characterization in human cells. Testing large numbers of sequences in cells presents a challenging problem as traditional assays are often complicated by splicing events that can occur during nuclear transcription and export (24). To test sequences under conditions that are not subject to nuclear processing, we developed a plasmid-based reporter assay that allows coupled transcription and translation to occur in the cytoplasm of human cells (FIG. 2A). We were inspired by an EMCV-driven system that relies on vaccinia virus (VACV) to circumvent nuclear expression (25). We inserted the sequences into a monocistronic firefly luciferase reporter plasmid (F-luc-mono) containing a VACV-specific promoter. Transfected HeLa cells were infected with VACV, and after a brief incubation, cells were lysed and assayed for luciferase activity. Plasmids carrying no-insert or a randomly chosen sequence from the starting pool provided a basal level of activity. We confirmed with no infection controls that luciferase activity was due to cytoplasmic expression by showing that uninfected cells have luciferase values equivalent to untreated cells. Plasmids carrying the selected sequences provided a range of activity (Fig. S1); the most active sequences enhanced translation ˜100-fold relative to the basal level after normalization for RNA (FIG. 2B). Analysis of the isolated RNA after six hours of expression demonstrated that the transcripts were intact and full-length. The top 9 sequences were validated in vitro in HeLa cell lysate to control for the strong capping mechanism associated with VACVs. The cell-free assay recapitulated the cell-based assay, confirming that activity did not depend on a 5′ cap or VACV infection (FIG. 2C).

To test whether the selected sequences were capable of internal translation initiation, we inserted the top 9 sequences from the monocistronic assay into a firefly reporter plasmid (F-luc-hp) containing a stable stem-loop structure (ΔG=−58 kcal/mol) to prevent ribosomal scanning (FIG. 3A) (26). Hairpin transcripts with no insert are poorly translated in vitro and in cells, yielding 0.3% and 1.5% of the respective activity observed for unobstructed transcripts after normalization for RNA (FIG. 3B). We confirmed that the RNA was stable in cells and in cell lysate, indicating that differences in activity were not due to selective degradation. We examined the top 9 sequences for IRES activity by first testing the reporter constructs in HeLa cell lysate. All nine sequences promote cap-independent translation initiation at levels consistent with known cellular IRESs (FIG. 3C) (26). We then examined the sequences in HeLa cells using cytoplasmic expression to avoid any possibility of nuclear splicing. In agreement with the in vitro assay, all of the sequences exhibit potent IRES activity (˜100-600-fold) when compared to the no insert control after normalization for RNA (FIG. 3D). To test for possible cryptic promoter activity, we repeated the cytoplasmic expression assay using a knock-out plasmid (F-luc-hp-ko) that deleted the VACV promoter. Under these conditions, HGL6.884 and HGL6.733 retain activity in VACV infected cells, indicating that a portion of their activity was due to monocistronic RNA that arose from a cryptic VACV promoter site. This prediction was confirmed by assaying HGL6.884 and HGL6.733 in uninfected cells, which yielded luciferase values equivalent to untreated cells (FIG. 3E). Direct transfection of the RNA-hairpin constructs into the cytoplasm of HeLa cells further corroborated our finding that all nine in vitro selected sequences mediate internal translation initiation (FIG. 3F).

Many well-characterized IRESs contain AUG triplets in their 5′ UTR that are expected to impede ribosomal scanning (2). Likewise, the human in vitro selected sequences identified in round 6 also have an abundance of AUG triplets. How is it then that a given AUG codon is selected as a start site when multiple options are present? One might expect a priori that AUGs in good sequence context would lead to more efficient translation initiation; however, only 1 out of 657 AUG codons observed in the 229 sequences contains a Kozak motif (Fig. S2) (27). To investigate this question, we selected ten sequences with a range of monocistronic activity and AUG triplet patterns, and examined their relative translation initiation efficiency and start site usage in vitro. This analysis revealed a number of striking observations (FIG. 4, A and B, and table S2). First, sequences with similar thermodynamic stability and no AUG codons can initiate translation with different levels of efficiency (HGL6.738 vs. HGL6.140). Second, out-of-frame start sites can be just as effective at translation initiation as in-frame start sites (HGL6.928 vs. HGL6.338). Third, AUG triplets near the 5′ end of the sequence are often bypassed in favor of downstream AUGs (e.g., HGL6.512, HGL6. 962, and HGL6.1155). Last, ribosomes that initiate translation at out-of-frame AUG codons can shift back into frame before reaching the designated ORF (e.g., HGL6.338, and HGL6.1155). Taken together, this data suggests that human cap-independent translation involves cis-regulatory elements in the 5′ UTR that function as ribosomal recruitment sites. This prediction is supported by the observation that many cellular IRESs have noncontiguous segments that retain IRES activity on their own (5, 28, 29).

To determine what role, if any, upstream AUG codons could play in ribosomal recruitment, we removed the in-frame, out-of-frame, and all AUG triplets from a high activity sequence (HGL6.877). Mutation of the AUG triplets had a strong negative impact on the translation initiation efficiency of all HGL6.877 variants (FIG. 4C). Even HGL6.877Δall devoid of all AUGs was less efficient than the parent sequence, indicating that AUGs can have a profound functional role in ribosomal recruitment. To determine whether translation initiation was due to the AUG codons or the surrounding sequence, we inserted the AUGs from HGL6.877 into an unselected sequence (HGL0.53) at the same locations that they appear in HGL6.877. Both HGL6.877 and HGL0.53 are identical in length, but HGL0.53 did not otherwise contain any AUG codons. HGL0.53 nor any of its AUG variants were capable of efficient translation initiation. This result demonstrates, at least for HG6.877, that presence of AUG triplets alone is not sufficient to initiate translation, but instead requires the ribosomal recruitment site in which the AUGs are imbedded for function.

Our results represent the first example of mRNA display as a genome-wide tool for identifying cap-independent translation initiation elements in the human genome. The in vitro selected IRESs characterized here represent novel regulatory elements that were previously hidden in the human genome. The general scheme used to identify these sequences is readily adaptable to other organisms and translation initiation mechanisms, and the versatility of the in vitro protocol makes it possible to explore ribosomal translation under a variety of conditions. We suggest that further discovery of additional cis-regulatory elements will advance our understanding of genome structure and function, and the biological role that IRESs play in the human genome.

Materials and Methods

Library Assembly and mRNA Display Selection

The human DNA library was provided by the Szostak laboratory¹⁸. This library was modified by PCR to add the genetic information necessary for performing mRNA display³¹. For each round of selection, the dsDNA library was transcribed with T7 RNA polymerase, photo-ligated to a psoralen-DNA-puromycin linker (5′-psoralen-TAGCCGGTG-(PEG₉)₂-A₁₅-ACC-puromycin) (SEQ ID NO:6), and translated in vitro by incubating the library (1 nmol) with rabbit reticulocyte lysate and ³⁵S-methionine for 1 hour at 30° C. Fusion formation was promoted by incubating the mixture overnight at −20° C. in the presence of KCl (600 mM) and MgCl₂ (75 mM). The mRNA-peptide fusion molecules were reverse transcribed, and purified by a two-step procedure on oligo (dT)-cellulose beads (NEB) and Ni-NTA agarose affinity resin (Qiagen). Functional TEEs were recovered by eluting the column with imidazole, dialyzing the sample into water, and amplifying the cDNA by PCR. The selection progress was monitored by determining the fraction of S³⁵-labeled mRNA-peptide fusions that remained on the oligo (dT) Ni-NTA affinity columns. After 6 rounds of selection and amplification, the dsDNA library was cloned and sequenced.

Luciferase Reporter Assay

A monocistronic luciferase reporter vector (pT7_v_<TEE>_FLuc) that contains both a T7 and a vaccinia virus synthetic late promoter was constructed by modifying a pT3-R-luc<IRES>F-luc(pA)₆₂ luciferase reporter plasmid provided by the Doudna laboratory (Gilbert et al., 2007)^(,32). HeLa and HEK-293 cells were seeded at a density of 15,000 cells per well in white 96-well plates 18 hours prior to transfection. Cells were transfected with a complex of the reporter plasmid (200 ng) and Lipofectamine 2000 (0.5 μl) in Opti-MEM (Invitrogen), and immediately infected with the Copenhagen strain (VC-2) of WT vaccinia virus at a multiplicity of infection (m.o.i) of 5 PFU/cell (FIG. 4). Cells were lysed (6.5 hours post-infection) in the 96-well plates and the luciferase activity was measured using the Promega Luciferase Assay System with a Glomax microplate luminometer (Promega). Cell-free characterization of the top TEEs was performed using the Human In Vitro Protein Expression Kit (Pierce). Luciferase expression was achieved following manufacturer's protocols using 300 ng of linear template for a two-hour transcription at 32° C. followed by a 90 min translation at 30° C.

RNA Characterization

A portion of the cells used in the transfect-infect study was separately lysed to evaluate the quality of the cellular RNA. Isolated RNA was reverse transcribed with Superscript II (Invitrogen), and realtime PCR was used to determine the mRNA levels of luciferase relative to the housekeeping gene hypoxanthine-guanine phospho-ribosyltransferase (HPRT). Using the ΔΔCt method, the amount of luciferase mRNA was normalized to HPRT mRNA levels. In addition, the length of luciferase mRNA was determined using PCR to analyze the relative proportion of the 5′- and 3′-ends of representative cDNA molecules.

Mutagenesis Study.

The 13-nucleotide core motif was assayed for activity by constructing five luciferase reporter constructs in which the 13-mer motif was either added to the 5′ end of a low activity TEE (clones 499, 646 and 347) or deleted from the 5′ end of a high activity TEE (clones 1092 and 1347). HGL sequences 1092 and 1347 were regenerated with the 13-nucleotide deletion by Klenow DNA polymerase extension followed by a restriction enzyme digest with BamHI and NcoI. The digested fragments were then ligated into the luciferase reporter plasmid pT7_v_<TEE>_FLuc. The insertion constructs were generated by overlap PCR, and then digested and ligated into the reporter plasmid. Translation enhancement of the modified sequences was assessed using the transfect/infect assay in HeLa cells. Sequences 1347 and 499 were additionally characterized in BSC40, RK13, BHK and 129SV cells.

Bioinformatics Analysis

Bioinformatics analysis was used to analyze 143 sequences from the naïve library, and 709 sequences isolated after six rounds of in vitro selection. The genomic locations of all non-redundant sequences were determined using the BLAT webtool to map each sequence to the human reference genome (hg18)²¹. This analysis revealed that 75 sequences from the naïve pool and 227 sequences from the round 6 pool matched with perfect sequence identity to the human reference genome. The program RepeatMasker was used to classify the selected sequences into specific repeat families³³. By randomly selecting 10,000 genomic locations, we generated the null expectation for the fraction of sequence motifs of length 200 nucleotides to overlap a repeat family. This number was 45.7% and was not statistically-significantly different from that observed for Round-0 sequences. However, the null hypothesis for TEEs is rejected at P<10-6 indicating that TEEs are significantly enriched in their involvement with repeat families.

TABLE 1 Clones sequenced for characterization after six rounds of mRNA display selection. Entry Clone Duplicates Sequence 1 HGL6.1 HGL6.346, AATCGAATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATCG HGL6.670, AAGAGAATCATCGAATGGACC (SEQ ID NO: 7) HGL6.676, HGL6.715, HGL6.961, HGL6.1106, HGL6.1182, HGL6.1338 2 HGL6.5 TGGAATCGAATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGA ATCGAAGAGAATCATCGAATGGACC (SEQ ID NO: 8) 3 HGL6.7 AGCATTCATATCTTGCAGTGTTGGGAAAGAGTGAGAGGTTGTGATGTCAAGAAG GATAGGTCAGAAGTGGAAGGTATGGGGGATTGTGCCTGCTGTCATGGCT (SEQ ID NO: 9) 4 HGL6.8 GGAACGAAATCGAATGGAACGGAATAGAATAGACTCGAATGTAATGGATTGCTA TGTAATTGATTCGAATGGAATGGAATCGAATGGAATGCAATCCAATGGAATGGA ATGCAATGCAATGAATGGAATGGAATGGAATGGAATGGAA (SEQ ID NO: 10) 5 HGL6.9 GGAACGAAATCGAATGGAACGGAATAGAATAGACTCGAATGTAATGGATTGCTA TGTAATTGATTCGAATGGAATGGAATCGAATGGAATGCAATCCAATGGAATGGA ATGCAATGCAATGAATGGAATGGAATGGAATGGAATGGA (SEQ ID NO: 11) 6 HGL6.12 TACGCAAATCGATAAATGTAATCCAGCATATAAACAGAACCAAAGACAAAAACC ACATGATTATCTCAATAGATGCAGAAAAGGCC (SEQ ID NO: 12) 7 HGL6.14 ACTCGAATGCAATCAACATCAAACGGAATCAAACGGAATTATCGAATGGAATCG AAGAGAATCATCGAACGGACTCGAATGGAATCATCTAATGGAATGGAATGG (SEQ ID NO: 13) 8 HGL6.18 GAAATTCCAATTAAAATGAAATCGACTTATCTTAACAAATATAGCAATGCTGACA ACACTTCTCCGGATATGGGTACTGCT (SEQ ID NO: 14) 9 HGL6.20 AAGGAAAAGTAAAAGGAACTTAACACCTTCAAGAAAAGACAGACAAATAACAA AACAGCAGTTTGATAGAATGAGATATCAGGGGATGGCA (SEQ ID NO: 15) 10 HGL6.21 ATCAACATCAAACGGAAAAAACGGAATTATCGAATGGAATCGAAGAGAATCATC GAACGGACC (SEQ ID NO: 16) 11 HGL6.22 AAAGAAAGACAGAGAACAAACGTAATTCAAGATGACTGATTACATATCCAAGAA CATTAGATGGTCAAAGACTTTAAGAAGGAATACATTCAAAGGCAAAAAGTCACT TACTGATTTTGGTGGAGTTTGCCACATGGAC (SEQ ID NO: 17) 12 HGL6.23 AAGGGAATTGAATAGAATGAATCCGAATGGAATGGAATGGAATGGAATGGAAT GGAATGGAATGGAATGGAATGGAATG (SEQ ID NO: 18) 13 HGL6.24 GAATGGAATCGAATCAAATTAAATCAAATGGAATGCAATAGAAGGGAATACAAT GGAATAGAATGGAATGGAATGGAATGGACT (SEQ ID NO: 19) 14 HGL6.25 ACAGCAAGAGAGAAATAAAACGACAAGAAAACTACAAAATGCCTATCAATAGT TACTTTAAATATCAGTGGACCAAATCAGTGAAACAAAAGACACAGAGTGGC (SEQ ID NO: 20) 15 HGL6.27 TAGCAGGAAACAGCAAACTCAAATTAAGTAATTTCAAGAGCGTATCATCAATGA ACTATTTTCAAAGATGTGGGCAAGAT (SEQ ID NO: 21) 16 HGL6.28 AAACGGAATTATCAAATGGAATCGAAGAGAATCATCGAACGGACTCGAATGGAA TCATCTAATGGAATGGAATGGAAG (SEQ ID NO: 22) 17 HGL6.30 GAATGAAATGAAATCAAATNGAATGTACATGAATGGAATAGAAAAGAATGCATC TTTCTCGAACGGAAGTGCATTGAATGGAAAGGAATCTACTGGAATGGATTCGAA TGGAATGGAANGGGATGGAATGGTATGG (SEQ ID NO: 23) 18 HGL6.32 AATGGACTCGAATGAAATCATCATCAAACGGAATCGAATGGAATCATTGAATGG AAAGGATGGGATCATCATGGAATGGAAACGAATGGAATCACTG (SEQ ID NO: 24) 19 HGL6.34 AATGGAATCATTGAATGGAATGGAATGGAATCATCAAAGAAAGGAATCGAAGG GAATCATCGAATGGAATCAAACGGAATCATCGAATGGAATGGAATGGAATG (SEQ ID NO: 25) 20 HGL6.38 HGL6.537 AGCAGAAGAAATAACTGAAATCAGAGTGAAACTGAATCAAATTGAGATGCAAA AATACATACGAAATGGCCAG (SEQ ID NO: 26) 21 HGL6.40 AGTTAATCCGAATAGAATGGAATGGAATGCAATGGAACGGAATGGAACGGAAT GGAATGGAATGGAATGGAATGGAATG (SEQ ID NO: 27) 22 HGL6.42 ATGGAATCAACATCAAACGGAATCAAACGGAATTATCGAATGGAATCGAAGAGA ATCATCGAACGGATTCGAATGGAATCATCTAATGGAATGGAATGGAAGAATCCA TGGACTCGAATGCAATCATCAGCGAATGGAATCGAATGGAATCATCGAATGGAC TCG (SEQ ID NO: 28) 23 HGL6.44 AAAGGAATGGACTGGAACAAAATGAAATCGAACGGTAGGAATCGTACAGAACG GACAGAAATGGAACGGCATGGAATGCACTCG (SEQ ID NO: 29) 24 HGL6.47 AAATCAACAACAAACGGAAAAAAAAGGAATTATCGAATGGAATCAAAGAGAAT CATCGAATGGACC (SEQ ID NO: 30) 25 HGL6.50 AAATGAACAAAACTAGAGGAATGACATTACCTGACTTCAAATTATACTACAGAG CTATAGTAACCAAAACAGCATGGTACAGGCAT (SEQ ID NO: 31) 26 HGL6.51 GTAATGGAATGGAATGGAAAGGAATCGAAACGAAAGGAATGGAGACAGATGGA ATGGAATGGAACAGAG (SEQ ID NO: 32) 27 HGL6.52 HGL6.496, ATCGAATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATCGA HGL6.881, AGAGAATCATCGAATGGACC (SEQ ID NO: 33) HGL6.1207 28 HGL6.57 CAATCAGAGCGGACACAAACAAATTGCATGGGAAGAATCAATATCGTGAAAATG GCC (SEQ ID NO: 34) 29 HGL6.59 AGACCTTTCTCAGAAGACACACAAATTGCCAACAGGTATATGAAAAAATGTTCA ATATCACTAATCATCAGGGCGATGCC (SEQ ID NO: 35) 30 HGL6.61 CATGGAATCGAATGGAATTATCATCGAATGGAATCGAATGGTACCAACACCAAA CGGAAAAAAACGGAATTATCGAATGGAATCGAAGAGAATCTTCGAACGGACC (SEQ ID NO: 36) 31 HGL6.63 GAACGATTTATCACTGAAAATTAATACTCATGCAAGTAGTAAACGAATGTAATG ACCATGATAAGGAGACGGACGGTGGTGATAGT (SEQ ID NO: 37) 32 HGL6.65 AAAGATCAANGNNCAAAAATCAGCAGCATTTCTATAAACCAACAATGTCCAGGC TGAGAGNGAAATCAAGAAANCAATTC (SEQ ID NO: 38) 33 HGL6.66 ACACACATACCAACAGAACATGACAAAAGAACAAAACCAGCCGCATGCATACTC GATGGAGACAAAGGTAACACTGCAGAATGGTGAAGGAAGAACAGTCATTTTAAT GACAGTGTTGGCT (SEQ ID NO: 39) 34 HGL6.67 HGL6.463, AATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATCGAAGA HGL6.775, GAATCATCGAATGGACC (SEQ ID NO: 40) HGL6.936 35 HGL6.68 ATCAAAAGGAACGGAATGGAATGGAATGGAATGGAATGGAATGGAATGGAATG GAATGAAATCAACCCGAATGGAATGGATTGGCATAGAGTGGAATGG (SEQ ID NO: 41) 36 HGL6.70 HGL6.71 TAAAGAAAAACAAACAAACAGAAATCAATGAAAATCCCATTCAAAGGTCAGCA ACCTCAAAGACTGAAGGTAGATAAGCCCACAAGGATG (SEQ ID NO: 42) 37 HGL6.73 AAACGGAAAAAAACGGAATTATCGAATGGAATCGAATAGAATCATCGAATGGA CC (SEQ ID NO: 43) 38 HGL6.74 GGAATCAACTCGATTGCAATGGAATGCAATGGAAAGGAATGGAATGCAATTAAA GCGAATAGAATGGAATGGAATGGAATGGAACGGAATGGAATG (SEQ ID NO: 44) 39 HGL6.76 GAAGAAGAAAAAACATGGATATACAATGTCAACAGAAATCAAGGAGAAACGGA ATTTCACCAATCAATTTAGTGATCTGGGTT (SEQ ID NO: 45) 40 HGL6.82 TGGAATCATCTAATGGAATGGAATGGAATAATCCATGGACTCGAATGCAATCAT CATAAAATGGAATCGAATGGAATCAACATCAAATGGAATCAAATGGGATCATTG AACGGAATTGAATGGAATCGTCAT (SEQ ID NO: 46) 41 HGL6.83 TGAACAGAGAATTGGACAAAACGCACAAAGTAAAGAAAAAGAATGAAGCAACA AAAGCAGAGATTTATTGAAAACAAAAGTACACACCACACAGGGTGGGAGTGG (SEQ ID NO: 47) 42 HGL6.85 HGL6.980, GGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATCGAAGAGAA HGL6.1002 TCATCGAATGGACC (SEQ ID NO: 48) 43 HGL6.88 AACACGACTTTGAGAAGAGTAAGTGATTGTTAATTAAAGCAAGAGAATTATTGA TGTATCACAGTCATGAGAAATATTGGAAGGAATATGGTCCATAC (SEQ ID NO: 49) 44 HGL6.91 TGAAAAGAAGAATGACCATAAGCAAGCAGATGAAAAACAAAACAGAATTTTTA CAGACGTCTTGGACTGATATCTTGGGC (SEQ ID NO: 50) 45 HGL6.92 AATCAATAAATGTAAACCAGCATATAAACAGAACCAACGACAAAAACCACATGA TTATCTCAATAGATGCAGAAAAGGCC (SEQ ID NO: 51) 46 HGL6.95 CAACATCAAACGGAATCAAACGGAATTATCGAATGGAATCGAAGAGAATCATCG AATGGACTCGAATGGAATCATCTAATGGAATGGAATGGAAG (SEQ ID NO: 52) 47 HGL6.96 AATGGAAGGGAATGGAATGGAATCGAATCGAATGGAACAGAATTCAATGGAAT GGAATGGAATGGAATGGAATCGAATGGAATGG (SEQ ID NO: 53) 48 HGL6.100 AAAGACTTAAACATAAGACCTAAAACCATAAAAACCACAGAAGAAAACATAGG CAATGCCATTCAGGACATAGGCATGGGCAAAGACTTC (SEQ ID NO: 54) 49 HGL6.101 AGACTTGAAAAGCACAGACAACGAAAGCAAAAATGGACAAATGGAATCACATC AAGCTAAAAGGTTTTGCATGGCAAAGG (SEQ ID NO: 55) 50 HGL6.1l2 HGL6.952, AGCAACTTCAGCAAAGTCTCAGGATACAAAATCAATGTGCAAAAATCACAAGCA HGL6.955 TTCTTATACACCAACAACAGACAAACAGAGAGCC (SEQ ID NO: 56) 51 HGL6.113 TGAATGCTATAGAGCAGTAAAAACAAATAAATGAACTACATTACAGCTACTTAC AACCATATGAAAGAATATAACCATAACAATGATGAGTGGACAAAAGCTAAGTGT GAAAGAATGCATAGTGCTACAGCAGCCAACATTTACAGC (SEQ ID NO: 57) 52 HGL6.115 AACAAAATTGAACAACATGCAAAGAAACATAAACGAAGCAATGAAAGTGTGCA GATCCACTGAAATGAAAGTGCTGTCCAGAGTGGGAGCCAGCTCGAGA (SEQ ID NO: 58) 53 HGL6.116 TGGAATTATCGTCGAATAGAATCGAATGGTATCAACATCAAACGGAAAAAAACG GAATTATCGAATGGAATCGAAGAGAATCATCGAACGGACTCGAATGGAATCATC TAATGGAATGGAATGGAATAATCCATGG (SEQ ID NO: 59) 54 HGL6.117 AGATAAGTGGATGAACAGATGGACAGATGGATGGATGGATGGATGGATGGATG GATGCCTGGAAGAAAGAAGAATGGATAGTAAGCTGGGTATA (SEQ ID NO: 60) 55 HGL6.119 AATCAAAGAATTGAATCGAATGGAATCATCTAATGTACTCGAATGGAATCACCA T (SEQ ID NO: 61) 56 HGL6.121 AATGGAATCGAACGGAATCATCATCAAACGGAACCGAATGGAATCATTGAATGG AATCAAAGGCAATCATGGTCGAATG (SEQ ID NO: 62) 57 HGL6.122 AGGAATCTATAATACAGCTGTTTATAGCCAAGCACTAAATCATATGATACAGAA AACAAATGCAGATGGTTTGAAGGGTGGG (SEQ ID NO: 63) 58 HGL6.125 AACGGAAAAAAACGGAATTATCGAATGGAATCGAAGAGAATCATCGAATGGAC C (SEQ ID NO: 64) 59 HGL6.126 TGAGAAAATGATGGAAAAGAGGAATAANACGAAACAAAACCACAGGAACACAG GTGCATGTGAATGTGCACAGACAAAGATACAGGGCGGACTGGGAAGGAAGTTTC TGCACCAGAATTTGGGG (SEQ ID NO: 65) 60 HGL6.132 AATGGAATCGAAGAGAATGGAAACAAATGGAATGGAATTGAATGGAATGGAAT TGAATGGAATGGGAAGGAATGGAGTG (SEQ ID NO: 66) 61 HGL6.134 AATGTCAAGTGGAATCGAGTGGAATCATCGAAAGAAATCGAATGGAATCGAAGG GAATCATTGGATGGGCTCAAAT (SEQ ID NO: 67) 62 HGL6.137 AAACAATGGAAGATAATGGAAAGATATCGAATGGAATAGAATGGAATGGAATG GACTCAAATGGAATGGACTTTAATGGAATGG (SEQ ID NO: 68) 63 HGL6.138 GAACAATCAATGGAAGCAGAAACAAATAAACCAAGGTGTGCATCAAGGAATAC ATTCACGCATGATGGCTGTATGAGTAAAATG (SEQ ID NO: 69) 64 HGL6.139 AAACCGAATGGAATGGAATGGACGCAAAATGAATGGAATGGAAGTCAATGGAC TCGAAATGAATGGAATGGAATGGAATGGAATG (SEQ ID NO: 70) 65 HGL6.140 AGGATACAAAATCAAAGTGCAAAAATCACAAGCATTCTTATACACCAATAACAG ACAAACAGAGAGCC (SEQ ID NO: 71) 66 HGL6.147 GGAATCGAATGGAATCAACATCAAACGGAAAAAAACAGAATTATCGTATGGAAT CGAATAGAATCATCGAATGGACC (SEQ ID NO: 72) 67 HGL6.148 CAACCCGAGTGGAATAAAATGGAATGGAATGGAATGAAATGGAATGGATCGGA ATGGAATCCAATGGAATCAACTGGAATGGAATGGAATGGAATG (SEQ ID NO: 73) 68 HGL6.149 TATCATCGAATGGAATCGAATGGAATCAACATCAAACGGAAAAAAACGGAATTA TCGAATGGAATCGAAGAGAATCATCGAATGGACC (SEQ ID NO: 74) 69 HGL6.150 CGGAATAATCATTGAACGGAATCGAATGGAATCATCATCGGATGGAAACGAATG GAATCATCATCGAATGGAAATGAAAGGAGTCATC (SEQ ID NO: 75) 70 HGL6.151 CAACACACAGAGATTAAAACAAACAAACAAACAATCCAGCCCTGACATTTATGA GTTTACAGACTGGTGGAGAGGCAGAGAAG (SEQ ID NO: 76) 71 HGL6.152 GGAATGGAATGAACACGAATGTAATGCAACCCAATAGAATGGAATCGAATGGCA TGGAATATAAAGAAATGGAATCGAAGAGAATGGAAACAAATGGAATGGAATTG (SEQ ID NO: 77) 72 HGL6.153 CACTACAAACCACGCTCAAGGCAATAAAAGAACACAAACAAATGGAAAAACAT TCCATGCTCATGGATGGG (SEQ ID NO: 78) 73 HGL6.158 AATCGAATGGAATTAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATCG AAGAGAATCATCGAATGGACC (SEQ ID NO: 79) 74 HGL6.161 TGGAAAAGAATCAAATTGAATGGCATCGAACGGAATGGGATGGAATGGAATAG ACCCAGATGTAATGGACTCGAATGGAATG (SEQ ID NO: 80) 75 HGL6.163 AATCAGTCTAGATCTTAAAGGAACACCAGAGGGAGTATTTAAATGTGCCCAATA AGCAAGAATTATGGTGATGTGGAAGTA (SEQ ID NO: 81) 76 HGL6.164 CCATAACACAATTAAAAACAACCTAAATGTCTAATAGAAGAACACTGTTCAGAC CGGGCATGGTGGCTTATACC (SEQ ID NO: 82) 77 HGL6.165 GACTAATATTCAGAATATACAAGGAACTCAAACAACTCAACAGTAGAAAAAAAA ACCTGAATAGACATTTCTCAAAAGAAGACATACAAATGGCC (SEQ ID NO :33) 78 HGL6.171 HGL6.1149 AACAGACCATAAATAAACACAGAAGACACACGAGTGTAAAGTCAGTGCCCCGCT GCGAATTAAATCGGGGTGATGTGATGGCGAGTGAGTGGGTAGTT (SEQ ID NO: 84) 79 HGL6.174 ATCATTGAATGCAATCACATGGAATCATCACAGAATGGAATCGTACGGAATCAT CATCGAATGGAATTGAATGGAATCATCAATTGGACTCGAATGGAAACATCAAAT GGAATCGATTGGAAGTGTCGAATGGACTCG (SEQ ID NO: 85) 80 HGL6.175 GGTCCATTCGATGATTCTCTTCGATTCCATTCGATAATTCCGTTTTTTCCCGTTTG ATGTTGATTCC (SEQ ID NO: 86) 81 HGL6.178 AGCAACTTCAGTAAAGTGTCAGGATACAAAATCAATGTGCAAAAATCACAAGCA TTCTTATACATCAATAACAGACAAACAGAGAGCCAAA (SEQ ID NO: 87) 82 HGL6.180 AGCAACTTCAGCAAAGTCTCAGGATACAAAATCAATGTGCAAAAATCACAAGCA TTCCTATACACCAACAACAGACAAACAGAGAGCC (SEQ ID NO: 88) 83 HGL6.181 GAATAATCATTGAACGGAATCGAATGGAATCATCATCGGATGGAAACGAATGGA ATCATCATCGAATGGAAATGAAAGGAGTCATC (SEQ ID NO: 89) 84 HGL6.182 HGL6.902 TAATCAT CT TCGAATTGAAAACAAAGCAATCATTAAATGTACTCTAACGGAATCA TCGAATGGACC (SEQ ID NO: 90) 85 HGL6.184 HGL6.1215 GGAATCGAATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAA TCGAAGAGAATCATCGAATGGACC (SEQ ID NO: 91) 86 HGL6.186 GATCAGCTTAGAATACAATGGAACAGAACAGATTAGAACAATGTGATTTTATTA GGGGCCACAGCACTGTTGACTCAAGTACAAGTTCTGACTCATGTAGAACTAACA CTTTT (SEQ ID NO: 92) 87 HGL6.187 AGAGAAAAGATGATCATGTAACCATTGAAAAGACAATGTACAAAACTAATACTA ATCACACAGGACCAGAAAGCAATTTAGACCAT (SEQ ID NO: 93) 88 HGL6.190 AATGGAATCGAATGGAATCAACATCAAACGGAAAAAACGGAATTATCGAATGG AATCAAAGAGAATCATCGAATGGACC (SEQ ID NO: 94) 89 HGL6.191 AATGGAATTATCATCGAATGGAATCGAATGGAATCAACATCAAACGGAAAAAAA CGGAATTATCGAATGGAATCGAAGAGAATCATCGAATGGACC (SEQ ID NO: 95) 90 HGL6.197 GTCAACACAGGACCAACATAGGACCAACACAGGGTCAACACAGGACCAACATA GGACCAACACAGGGTCAACACAAGACCAACATGGGACCAACACAGGGTCAACA TAGGACCAACATGGGACCAACACAGGGTCAACACAGGACCAAC (SEQ ID NO: 96) 91 HGL6.198 TATAGTTGAATGAACACACATACACACACACATGCCACAAAACAAAAACAAAGT TATCCTCACACACAGGATAGAAACCAAACCAAATCCCAACACATGGCAAGATGA T (SEQ ID NO: 97) 92 HGL6.206 GAATCAACTCGATTGCAATCGAATGGAATGGAATGGTATTAACAGAATAGAATG GAATGGAATGGAATGGAACGGAACG (SEQ ID NO: 98) 93 HGL6.208 AATGGAATGGAATAATCGACGGACCCGAATGCAATCATCATCGTACAGAATCGA ATGGAATCATCGAATGGACTGGAATGGAATGG (SEQ ID NO: 99) 94 HGL6.210 AATACAAACCACTGCTCAACGAAATAAAAGAGGATACAAACAAATGGAAGAAC ATTCTATGCTCATGGGTAGGATGAATTCATATCGTGAAAATGGCCATACTGCC (SEQ ID NO: 100) 95 HGL6.215 AAACACGCAAACACACACACAAGCACACTACCACACAAGCGGACACACATGCA AACACGCGAACACACACACATATACACACAAGCACATTACAAAACACAAGCAA ACACCAGCAGACACACAAACACACAAACATACATGG (SEQ ID NO: 101) 96 HGL6.219 AATCGAACGGAATCAACATCAAACGGAAAAAAAACGGAATTATCGAATGGAAT CGAAGAGAATCATCGAATGGACC (SEQ ID NO: 102) 97 HGL6.220 HGL6.301, ACACATTTCAAGGAAGGAAACAAGAACAGACAGAAACACAACATACTTCATGA HGL6.1353 AACCACATTTTAGCATCCTGGCCGAGTATTCATCA (SEQ ID NO: 103) 98 HGL6.222 GGATACAAAATCAATGTACAAAAATCACAAGCATTCTTATACACCAATAACAGA CAAACAGAGAGCC (SEQ ID NO: 104) 99 HGL6.223 TAATTGATTCGAATGGAATGGAATAGAATGGAATTGAATGGAATGGACCATAAT GGATTGGACTTTAATAGAAAGGGCATG (SEQ ID NO: 105) 100 HGL6.225 AGCAACTTCAGCAAAGTCTCAGGATACAAAATCAATGTACAAAAGTCACAAGCA TTCTTATACACCAACAAAAGACAAACAGAGAGCC (SEQ ID NO: 106) 101 HGL6.228 ACATCAAACGGAAAAAAAAAACAAAACGGAATTATCGAATGGAATCGAAGAGA ATCATCGAATGGACC (SEQ ID NO: 107) 102 HGL6.229 ACATCTCACTTTTAGTAATGAACAGATCATTCAGACAGAAAATTAGCAAAGAAA CATCAGAGTTAAACTACACTCTAAACCAAATGGACCTA (SEQ ID NO: 108) 103 HGL6.231 GAAGAAAGCATTCATTCAAGACATCTAACTCGTTGATATAATGCATACAGTTCAA AATGATTACACTATCATTACATCTAGGGCTTTC (SEQ ID NO: 109) 104 HGL6.232 GCAAAAGAAACAATCAGTAGAGTAAACAGACAACTCATAGAATGCAAGAAAAT CATCGCAATCTGTACATCCAACAAAGGGCT (SEQ ID NO: 110) 105 HGL6.235 ACACACACATTCAAAGCAGCAATATTTACAACAGCCAAAAGGTGGAAACAATTG AGCAATTG (SEQ ID NO: 111) 106 HGL6.237 ATCATCGAATAGAATCGAATGGTATCAACACCAAACGGAAAAAAACGGAATTAT CGAATGGAATCGAAGAGAATCTTCGAACGGACC (SEQ ID NO: 112) 107 HGL6.238 TGAAAATACAAATGACCATGCAAGTAATTCCGCAGGGAGAGAGCGGATATGAAC AAACAGAAGAAATCAGATGGGATAGTGCTGGCGGGAAGTCA (SEQ ID NO: 113) 108 HGL6.239 AATCGAAAGGAATGTCATCGAATGGAATGGACTCAAATGGAATAGAATCGGATG GAATGGCATCGAATGGAATGGAATGGAATTGGATGGAC (SEQ ID NO: 114) 109 HGL6.241 AACATGAACAGTGGAACAATCAGTGAACCAATACAAGGGTTAAATAAGCTAGCA ATTAAAAGCTGTATCACTGGTCTAAAGATAGAAGATCAAGTAGAAAATCAGCGC AAGAGGAAAGATATACGAAAACTAATGGCC (SEQ ID NO: 115) 110 HGL6.243 CGAATGGAATCATTATGGAATGGAATGAAATGGAATAATCAAATGGAATTGAAT GGAATCATCGAATGGAATCGAACAAAATCCTCTTTGAATGGAATAAGATGGAAT CACCAAATGGAATTG (SEQ ID NO: 116) 111 HGL6.246 AAACGGAATCAAACGGAATTATCGAATGGAATCGAAGAGAATCATCGAACGGA CTCGAATGGAATCATCTAATGGAATGGAATGGAAGAATCCATGGACT (SEQ ID NO: 117) 112 HGL6.247 GCTAGTTCAACATATGCAAATCAATAAACGTAATCCATCACATAAACAGAACCA ATGACAAAAACCACGATTATCTCAATAGATGCAGAAAAGGCC (SEQ ID NO: 118) 113 HGL6.256 ACCAATCAAGAAAACAATGCAACCCACAGAGAATGGACAAAAGCAAGGCAGGA CAATGGCT (SEQ ID NO: 119) 114 HGL6.26 ATCGAATGGAATCAACATCAGACGGAAAAAAACGGAATTATCAAATGGAATCGA AGAGAATCATCGAATGGACC (SEQ ID NO: 120) 115 HGL6.260 ATGGAATCAACATCAAACGGAAAAAAAAACGGAATTATCGAATGGAATCGAAG AGAATCATCGAATGGACCAGAATGGAATCATCTAATGGAATGGAATGG (SEQ ID NO: 121) 116 HGL6.261 HGL6.1088 AATGGAATCATCATCGAATGGAATCGAATGGAATCATGGAATGGAATCAAATGG AATCAAATGGAATCGAATGGAATGGAATGGAATG (SEQ ID NO: 122) 117 HGL6.262 AACGGAATCAAACGGAATTACCGAATGGAATCGAATAGAATCATCGAACGGACT CGAATGGAATCATCTAATGGAATGGAATGGAAG (SEQ ID NO: 123) 118 HGL6.263 AAACGGAATCAAACGGAATTATCGAATGGAATCGAAAAGAATCATCGAACGGA CTCGAATGGAATCATCTAATGGAATGGAATGGAAGAATCCATGG (SEQ ID NO:  124) 119 HGL6.266 AGCAACTTCAGCAAAGTCTCAGGATACAAAATCAATGTACAAAAATCACAAGCA TTCTTATACACCAATAACAGACAAACAGAGAGCC (SEQ ID NO: 125) 120 HGL6.267 GAATGATACGGANTANNNNGNAATGGAACGAAATGAAATGGAATGGAATGGAA TGGAATGGAATGGAATGG (SEQ ID NO: 126) 121 HGL6.268 AATGGACTCGAATGGATTAATCATTGAACGGAATCGAATGGAATCATCATCGGA TGGTAATGAATGGAATCATCATCGAATGGAATCGG (SEQ ID NO: 127) 122 HGL6.271 GAATGGAATCGAAAGGAATGTCATCGAATGGAATGGAATGGAACGGAATGGAA TCGAATGGAATGGACTCGAATGGAATAGAATCGAATGCAATGGCATCG (SEQ ID NO: 128) 123 HGL6.274 HGL6.466, GAATAGAATAGAATGGAATCATCGAATGGAATCGAATGGAATCATCATGATATG HGL6.883 GAATTGAGTGGAATC (SEQ ID NO: 129) 124 HGL6.276 TAAGCCGATAAGCAACTTCAGCAAAGTCTCAGGAGACAAAATCAATGTGCAAAA AATCACAAGCATTCTTATACACTAATAACAGACAAACAGAGAGCCAAATCATG (SEQ ID NO: 130) 125 HGL6.277 AGCAACTTCAGCAAAGTCTCAGGATACAAAATCAATGTGCAAAAATCAAAAGCA TTCTTATGCACCAATAACAGACACAGAGCCAAAT (SEQ ID NO: 131) 126 HGL6.278 AGGAAAGTTTTCAATATGAGAAAGATACAAACCAACAGAATAAGCAAACTGGAT AAACAGAAAATACAGAGAGAGCCAAGG (SEQ ID NO: 132) 127 HGL6.280 AATGGAATGGAACGCAATTGAATGGAATGGAATGGAACGGAATCAACCTGAGTC AAATGGAATGGAATGGAATGGAATG (SEQ ID NO: 133) 128 HGL6.289 AGGAAAATGCAAATCAGAACGACTATAACACACCATCTCAAACTCGTTAGGATG GCTATTATCAAAAAGTCAAGAGATAACAAATGTGGGCAAGGG (SEQ ID NO: 134) 129 HGL6.290 GGAACGAAATCGAATGGAACGGAATAGAATAGACTCGAATGTCATGGATTGCTA TGTAATTGATTGGAATGGAATGGAATCG (SEQ ID NO: 135) 130 HGL6.291 GAATTGAAAGGAATGTATTGGAATAAAATGGAATCGAATAGGTTGAAATACCAT AGGTTCGAATTGAATGGAATGGGAGGGACACCAATGGAATTG (SEQ ID NO: 136) 131 HGL6.292 AACAAAACAAAAACCCAACTCAATAACAAGAAGACAAACAACCCAATTTAAAA TGAGCAAAGAACTTGATAAACATGTCTCCAAAGAAGATACGGCCAAAGAGCAC (SEQ ID NO: 137) 132 HGL6.295 ATGGTTAAAACTCAACAATGAAAACACAAACAGCGCAATTTAAAAATGGGCAAA ATGACAGGCCAGACCCAGTGGCTCATGCG (SEQ ID NO: 138) 133 HGL6.300 AAGCAACTTCAGCAAAGTCTCGGGATACAAAATCAATGTGCAAAAATCACAAGC ATTCTTATACACCACTAACAGACAAATGGAGAGTC (SEQ ID NO: 139) 134 HGL6.302 GAATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATCGAAG AGAATCATCGAATGGACCAGAATGGAATCATCTAATGGAATGGAATGGAATAAT CCATGG (SEQ ID NO: 140) 135 HGL6.305 TAGAAGGAATTTGATACATGCTCAGAAATACAGGCAAAGGAAGTAGGTGCCTGC CAGTGAACACAGGGGAACTATGGCTCCTA (SEQ ID NO: 141) 136 HGL6.310 GGAATCGAATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAA TCGAAGAGAATCATCGAATGGACC (SEQ ID NO: 142) 137 HGL6.311 AACTAAGACAACAGATTGATTTACACTACTATTTTCACACAGCCAAAAATATCAC TATGGCAATCGTCAAAAGGTCAATTCAAAGATGGGACAGT (SEQ ID NO: 143) 138 HGL6.315 AAAAGCAATTGGACTGATTTTAAATATACGTGGCAACAAGGATAAACTGCTAAT GATGGGTTTGCAAATACAGATCG (SEQ ID NO: 144) 139 HGL6.317 HGL6.1189 AATGGAATCAACATCGAACGGAAAAAAACGGAATTATCGAATGGAATCGAAGA GAATCATCGAATGGACC (SEQ ID NO: 145) 140 HGL6.319 TGCAAGATAACACATTTTAGTTGACACCATTGAAAACAGTTTTAACCAAGAATAT TAGAACCAATGAAGCAGAGAAATCAAAAGGGTGGATGGAACTGCCAAAGGATG (SEQ ID NO: 146) 141 HGL6.321 TAGAACAGAATTGAATGGAATGGCATCAAATGGAATGGAAACGAAAGGAATGG AATTGAATGGACTCAAATGTTATGGAATCAAAGGGAATGGACTC (SEQ ID NO: 147) 142 HGL6.323 AAGAGAATCATCGAATGGAATCGAATGGAATCAACATCAAACGGAAAAAAACG GAATTATCGAATGGAATCGAAGAGAATCATCGAATGGACC (SEQ ID NO: 148) 143 HGL6.324 HGL6.431, ATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATCGAAGAGAATCAT HGL6.1071 CGAATGGACC (SEQ ID NO: 149) 144 HGL6.326 GAATCAACATCAAACGGAAAAAAACCGAATTATCGAATGGAATCGAAGAGAAT CATCGAATGGACC (SEQ ID NO: 150) 145 HGL6.327 ATCAACATCAAACGGAATCAAACGGAATTATCGAATGGAATCGAAGAGAATCAT CAAATGGACTCGAATGGAATCATCTAATGGAATGGAATGGAAGAATCCATGG (SEQ ID NO: 151) 146 HGL6.330 HGL6.1005 AAACAGTTCAAAAATTATTGCAACAAAATGAGAGAGATGAGTTTATCTTGCAAA CTAATGGATGGTAGCAGTGACAGTGGCAAAACGTGGTTTGATTCT (SEQ ID NO: 152) 147 HGL6.334 ATCGAATGGAATCATTGAATGGAAAGGAATGGAATCATCATGGAATGGAAACGA ATGGAATCACTGAATGGACTCGAATGGGATCATCA (SEQ ID NO: 153) 148 HGL6.335 ATTCAGCCTTTAAAAAAAGAAGACAGTCCTGTCATTTGTGACAATATGAATGAA ACAGACATCACATTAAATGAAATGAGCCAGGCGCAG (SEQ ID NO: 154) 149 HGL6.336 AGGAGAATAGCAGTAGAATGACAAAATTAGATTTTCACATGAAACTTGATGACA GTGTAGGAAATGGACTGAAAGGACAAGAC (SEQ ID NO: 155) 150 HGL6.337 HGL6.1095, AACCCACAAAGACAACAGAAGAAAAGACAACAGTAGACAAGGATGTCAACCAC HGL6.1367 ATTTTGGAAGAGACAAGTAATCAAACACATGGCA (SEQ ID NO: 156) 151 HGL6.338 GAAAATGAACAATATGAACAAACAAACAAAATTACTACCCTTACGAAAGTACGT GCATTCTAGTATGGTGACAAAAAGGAAAG (SEQ ID NO: 157) 152 HGL6.339 AACATCAAACGGAATCAAACGGAATTATCGAATGGAATCGAAGAGAATCATCGA ACGGACTCGAATGGAATCATCTAATGGAATGGAATGGAAGAATCCATGGACTCG AATGCAATCATCATCGAATGAAATCGAATGGAATCATCGAATGGACTCG (SEQ ID NO: 158) 153 HGL6.340 ACCAACATAAGACAAAGAAACATCCAGCAGCTGCCTATGGCAAAAGATTACAAT GTGTCAAACAAGAGGGCAATG (SEQ ID NO: 159) 154 HGL6.342 ATGGAATTCAATGGAATGGACATGANTGNAATGNACTTCAATGGAATGGNATCN AATGGAATGNAATTCANT (SEQ ID NO: 160) 155 HGL6.343 TATGACTTTCACAAATTACAGAAAAAGACACCCATTTGACAAGGGAACTGAAGG TGGTGAAGACATACTGGCAGGCTAC (SEQ ID NO: 161) 156 HGL6.344 AATGGAAAGGAATCGAATGGAAGGGAATGAAATTGAATCAACAGGAATGGAAG GGAATAGAATAGACGGCAATGGAATGGACTCG (SEQ ID NO: 162) 157 HGL6.347 AGCCTATCAAAAAGTGGGCTAAGAATATGAATACACAATTCTCAAAAGAAGATA TACAAATGGGCAACAAACATATGAAAACATACTCAACATCACTAATGATCAGGG AAATG (SEQ ID NO: 163) 158 HGL6.352 HGL6.710 AGCAACTTCAGCAAAGTATCAGGATACAAAATCAATGTACAAAAATCCCAAGCA TTCTTATACACCAACAACAGACAAACAGAGAGCC (SEQ ID NO: 164) 159 HGL6.353 AAAGACAATATACAAATGGCCAATAAGCACATGAAAAGACGCTCAACATCCTTA GTCGTTAAGGCAATGCAAATCAAAACCACAATG (SEQ ID NO: 165) 160 HGL6.354 AGCAACTTCAGCAAAGTCTCAGGATACAAAATCGATGTGCAAAAATCACAAGCA TTCTTATACACCAACAACAGATAAACAGAGAGCC (SEQ ID NO: 166) 161 HGL6.356 AACGGAAAAAAAACGGAATTATCGAATGGAATCGAAGAGAATCATCGAATGGA CCAGAATGGAATCATCTAATGGAATGGAATGGAATAATCCATGGACTCGAATG (SEQ ID NO: 167) 162 HGL6.357 AACAGCAATAGACACAAAGTCAGCACTTACAGTACAAAAACTAATGGCAAAAGC ACATGAAGTGGGACAT (SEQ ID NO: 168) 163 HGL6.358 GGAATCAAACGGAATTATCGAATGGAATCGAAGAGAATCATAGAACGGACTCAA ATGGAATCATCTAATGGAATGGAATGGGAGAATCCATGGACTCGAATG (SEQ ID NO: 169) 164 HGL6.360 HGL6.1105 AATGGAATCAATATCAAACGGAAAAAAACGGAATTATCGAATGGAATCGAAGA GAATCATCGAATGGACC (SEQ ID NO: 170) 165 HGL6.362 AAAATGATCATGAGAAAATTCAGCAACAAAACCATGAAATTGCAAAGATATTAC TTTTGGGATGGAACAGAGCTGGAAGGCAAAGAG (SEQ ID NO: 171) 166 HGL6.364 AACGGAATCAAACGGAATTATCGAATGGAATCGAAAAGAATCATCGAACGGACT CGAATGGAATCATCTAATGGAATGGAATGGAAGAATCCATGG (SEQ ID NO: 172) 167 HGL6.367 AAACGGAATTATCGAANGGAATCAAAGAGAATCATCGAANNNNNACGAATGGA ATCATATAATGGAATGGAATGGAATAATCCATGGACC (SEQ ID NO: 173) 168 HGL6.369 AATGGAATCGAATGGATTGATATCAAATGGAATGGAATGGAAGGGAATGGAATG GAATGGAATTGAACCAAATGTAATGGATTTG (SEQ ID NO: 174) 169 HGL6.371 TAAAAGACGGAACAGATAGAAAGCAGAAAGGAAAGGTGAATTGCATTACCACT ATTCATACTGCCACACACATGACATTAGGCCAAGTC (SEQ ID NO: 175) 170 HGL6.372 ACAAACAATCCAATTCGAAAATGGGCAAGATATTTCACCAAAGACATGAGCTGA TATTTCAC (SEQ ID NO: 176) 171 HGL6.373 AATGGAATCGAATGGAACAATCAAATGGACTCCAATGGAGTCATCTAATGGAAT CGAGTGGAATCATCGAATGGACTCG (SEQ ID NO: 177) 172 HGL6.374 TAACACATAAACAAACACAGAGACAAAATCTCCGAGATGTTAATCTGCTCCAGC AATACAGAACAATTTCTATTACCAACAGAATGCTTAATTTTTCTGCCT (SEQ ID NO: 178) 173 HGL6.379 GGAATCGAATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAA TCAAAGAGAATCATCGAATGGACC (SEQ ID NO: 179) 174 HGL6.382 AGAATGGAAAGGAATCGAAACGAAAGGAATGGAGACAGATGGAATGGAATG (SEQ ID NO: 180) 175 HGL6.383 GAATGGAATGGAAAGGAATCGAAACGAAAGGAATGGAGACAGATGGAATGGAA TGGAACAGAGAGCAATGG (SEQ ID NO: 181) 176 HGL6.387 GAATCATCATAAAATGGAATCGAATGGAATCAACATCAAATGGAATCAAATGGT CTCGAATGGAATCATCTTCAAATGGAATGGAATGG (SEQ ID NO: 182) 177 HGL6.389 AACAACAATGACAAACAAACAACAACGACAAAGACATTTATTTGGTTCACAAAT CTCCAGGGTGTACAAGAAGCATGGTGCCAGCATCTGCTCAGCTTCTGATGAGGG CTCTGGGAAGCTTTTACTC (SEQ ID NO: 183) 178 HGL6.390 AACGGACTCGAACGGAATATAATGGAATGGAATGGATTCGAAAGGAATGGAAT GGAATGGACAGGAAAAGAATTGAATGGGATTGGAATGGAATCG (SEQ ID NO: 184) 179 HGL6.393 AGGAAATAAAAGAAGACACAAACAAATGGAAGAACATTCCATGCTTATGGATA GGGAGAATCAGTATCGTGAAAATGGCCATACT (SEQ ID NO: 185) 180 HGL6.394 HGL6.1136 AACATCAAACGAAATCAAACGGAATTATCAAATTGAATCGAAGAGAATCATCGA ATTGCCACGAATGCAATCATCTAATGGTATGGAATGGAATAATCCATGGACCCA GATG (SEQ ID NO: 186) 181 HGL6.395 AGAAATTAACAGCAAAAGAAGGATGCAGTGCAACTCAGGACAACACATACAATT CAAGCAACAAATGTATAGTGGCTGGGCACCAAGGATACAG (SEQ ID NO: 187) 182 HGL6.396 GCAATAAAATCGACTCAGATAGAGAAGAATGCAATGGAATGGAATGGAATGGA ATGGAATGGGATGGAATGGTATGGAATGG (SEQ ID NO: 188) 183 HGL6.397 CCACATAAAACAAAACTACAAGACAATGATAAAGTTCACAACATTAACACAATC AGTAATGGAAAAGCCTAGTCAATGGCAG (SEQ ID NO: 189) 184 HGL6.399 GGACAACATACACAAATCAGTCAAGATACATCATTTCAACAGAATGAAAGACAA AAACCATTTGATCACTTCAATCGATGATGAAAAAGCA (SEQ ID NO: 190) 185 HGL6.400 GAAATCATCATCAAACGGAATCGAATGGAATCATTGAATGGAATGGAATGGAAT CATCATGGAATGGAAACG (SEQ ID NO: 191) 186 HGL6.405 TGGAATGGANTGGAATGNAATCNAATCNNNTGGTAATGAATCAAATGGAATCAA ATCGAATGGNAATAATGGAATCNANNGGAAACGAATGGNATCGAATTGCACTGA TTCTACTGACTTCGAGGAAAATGAAATGAAATGCGGTGAAGTGGAATGG (SEQ ID NO: 192) 187 HGL6.409 AGCAACTTCAGCAAAGTCTCAGGATACAAAATCAATGGGAAAAAATCACAAGCA TTCCTATACATCAATAACAGACAAACAGAGAGCC (SEQ ID NO: 193) 188 HGL6.410 GAATGTTATGAAATCAACTCGAACGGAATGCAATAGAATGGAATGGAATGGAAT GGAATGGAATGGAATGG (SEQ ID NO: 194) 189 HGL6.412 AGTAGAATTGCAATTGCAAATTTCACACATATACTCACACACAAGTACACACATC CACTTTTACAACTAAAAAAACTAGCACCCAGGACAGGTGCAGTGGCT (SEQ ID NO: 195) 190 HGL6.416 GGAATCAACATCAAACGGAAAAAAAACGGAATTATCGAATGGAATCGAAGAGA ATCATCGAATGGACC (SEQ ID NO: 196) 191 HGL6.420 GGAATAATCATCATCAAACAGAACCAAATGGAATCATTGAATGGAATCAAAGGC AATCATGGTCGAATG (SEQ ID NO: 197) 192 HGL6.422 ACTCAGGAAAAATAACGAATCCAACTCACAGGAGAAAGAAGTACAAACCAGAA ACCAATTTCAAATTACAAGGACCAGAATACTCATGTTGGCTGGCCAGT (SEQ ID NO: 198) 193 HGL6.424 AAACGCACAAACAAAGCAAGGAAAGAATGAAGCAACAAAAGCAGAGATTTATT GAAAATGAAAAATACACTCCACAGGGTGGG (SEQ ID NO: 199) 194 HGL6.429 GCATAGAATCGAATGGAATTATCATTGAATGGAATCGAATGGAATCAACATCAA ACGGAAAAAAACGGAATTATCGAATGGAATCGAAGAGAATCATCGAATGGACC C (SEQ ID NO: 200) 195 HGL6.430 AATGGAATCGAANAGAATCATCGAACGGACTCGAATGGAATCATCTAATGGAAT GGAATGGAATAATCCATGGACCCGAATG (SEQ ID NO: 201) 196 HGL6.433 AAATGAATCGAATGGAATTGAATGGAATCAAATAGAACAAATGGAATCGAAATG AATCAAATGGAATCGAATCGAATGGAATTGAATGGCATGGAATTG (SEQ ID NO: 202) 197 HGL6.436 NTCACAATCACACAACACATTGCACATGNNNANNATGCACTCACAATACACACA CAACACATACACAACACACATGCAATACAACACAAAACGCAACACAACATATAC ACNACACACAGCACACANATGCC (SEQ ID NO: 203) 198 HGL6.442 GAATGGAATCAAATCGAATGAAATGGAATGGAATAGAAAGGAATGGAATGAAA TGGAATGGAAAGGATTCGAAT (SEQ ID NO: 204) 199 HGL6.445 AAAGACTTAAACGTTAGACCTAAAACCATAAAAACCCTAGAGGAAAACCTAGGC ATTACCATTCAGGACTTAGGCATGGGCAAGGAC (SEQ ID NO: 205) 200 HGL6.446 GTTTACAGTCAAGTGTACAAACAGAATATAAGCAAACAAAAGAGAACATATACT TACAAACTATGCTAAGTGCCATGAAGGAAAAG (SEQ ID NO: 206) 201 HGL6.447 AAAGTCCAAAGATGAACAAAATATCCAGAAGGAAAACAAATGCACTTGGGGAG TGGGAAAGAAAACCAAGACTGAGCAATGCGTCAAGCTCAGACGTGCCTCACTAC G (SEQ ID NO: 207) 202 HGL6.448 AAACGGAATCAAACGGAATTATCGAATGGAGTCGAAAAGAATCATCGAACGGA CTCGAATGGAATCATCTAATGGAATGGAATGGAAGAATCCATGG (SEQ ID NO: 208) 203 HGL6.450 HGL6.1296 AATTGATTCGAAATTAATGGAATTGAATGGAATGCAATCAAATGGAATGGAATG TAATGCAATGGAATGTAATAGAATGGAAAGCAATGGAATG (SEQ ID NO: 209) 204 HGL6.453 TACAGAACACATGACTCAACAACAGCAGAAAGCATATTCTTTTCAAATGCACAT GAAACATTATCATGATGGACCAAAT (SEQ ID NO: 210) 205 HGL6.454 TAAGACACATAGAAAACATAAAGCAAAATGGCAGATGTAAATGCAACCTATCAA TCAAAACATTACGAATGGCTT (SEQ ID NO: 211) 206 HGL6.456 GGAACAAAATGAAATCGAACGGTAGGAATCATACAGAACAGAAAGAAATGGAA CGGAATGGAATG (SEQ ID NO: 212) 207 HGL6.457 AACGGAAAAAACGGAATTATCGAATGGAATCGAAGAGAATCATCGAATGGAAT CGAATGGAGTCATCG (SEQ ID NO: 213) 208 HGL6.459 HGL6.806 AACATACGAAAATCAATAAACGTAATCCAGCATATAAACAGAACCAAAGACAA AAACCACATGATTATCTCAATAGATGCAGAAAAGGCCTTT (SEQ ID NO: 214) 209 HGL6.460 HGL6.1163 AATCGAACGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATC GAAGAGAATCATCGAATGGACC (SEQ ID NO: 215) 210 HGL6.461 AGAATGGAATGCAATAGAATGGAATGCAATGGAATGGAGTCATCCGTAATGGAA TGGAAAGGAATGCAATGGAATGGAATGGAATGG (SEQ ID NO: 216) 211 HGL6.462 GGAATAAAACGGACTCAATAGTAATGGATTGCAATGTAATTGATTCGATTTCGA ATGGAATCGCATGGAATGTAATGGAATGGAATGGAATGGAAGGC (SEQ ID NO: 217) 212 HGL6.467 AGCAACTTCAGCAAAGTCTCAGGATACAAAATCAATGTACAAAAATCACAAGCA TTCTTATACACCAACAACAGACAAACAGAGAGCC (SEQ ID NO: 218) 213 HGL6.476 TAAGCAGAGAAAATATCAACACGAAAATAATGCAAGGAGAAAAATACAGAACA ATCCAAAATGTGGCC (SEQ ID NO: 219) 214 HGL6.487 AATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGTATGGAATCGAAAA GAATTATCGAATGGACC (SEQ ID NO: 220) 215 HGL6.489 HGL6.587 TCAAACGGAAAAAAACGGAATTATCGAATGGAATCGAAGAGAATCATCGAATG GACC (SEQ ID NO: 221) 216 HGL6.490 AACTTCAGCAAATTCTCAGGATACAAAATCAATGTGCAAAAACCACAAGCATTC CTATACACCAATAATAGACAGTGAGCCAAAT (SEQ ID NO: 222) 217 HGL6.494 HGL6.1131 ACATCAAACGGAATCAAACGGAATTATCGAATGGAATCGAAAAGAATCATCGAA CGGACTCGAATGGAATCATCTAATGGAATGGAATGGAAGAATCCATGGACTCGA ATG (SEQ ID NO: 223) 218 HGL6.497 AATGGAATCGAATGCAATCATCGAACGGAATCGAATGGCATCACCGAATGGAAT GGAATGGAATGGAATGGAATGG (SEQ ID NO: 224) 219 HGL6.499 AATCCAGCATATAAACAGAACCAAAGACAAAAACCACATGATTATCTCAATAGA TGCAGAAAAGGCC (SEQ ID NO: 225) 220 HGL6.500 TGACTAAACAGAGTTGAACAAGAACAAAAAGCAAATTTGCAGAAATGAAATAC ATACTAATTGAAAGTCCATGGACAGGCTCAACAGATGATATAGATACAGCTAAA GAGATAATTAGTGAAATGGATCAG (SEQ ID NO: 226) 221 HGL6.501 GATCATCAGAGAAACAGAGAAATGCAAATTAAAACCACAATGAGATACTATCTC CACACAAGTCAGAATGGCTAT (SEQ ID NO: 227) 222 HGL6.503 AGGATACAAAATCAATGTACAAAAATCACAAACATTCTTATACACCAACAACAG ACAAACAGAGAGCCAAATCATGGGTG (SEQ ID NO: 228) 223 HGL6.505 TAAGCAACTTCAGCAAAGTCTCAGGATACAAAATCAATGTACAAAAATCACAAG CATTCTTATACACCAACAACAGACAAACAAGAGTGCCAAATCATG (SEQ ID NO: 229) 224 HGL6.506 AGAATTGATTGAATCCAAGTGGAATTGAATGGAATGGAATGGATTAGAAAGGAA TGGAATGGATTGGAATGGATTGGAATGGAAAGG (SEQ ID NO: 230) 225 HGL6.508 AATGGAATGCAATCGAATGGAATGGAATCGAACGGAATGGAATAAAATGGAAG AAAACTGGCAAGAAATGGAATCG (SEQ ID NO: 231) 226 HGL6.509 AACTGCATCAACTAACAGGCAAAATAACCAGCTAATATCATAATGACAGGATTA AATTCACAAATGACAATATTAACCGTAAATGTAAATGGGCTA (SEQ ID NO: 232) 227 HGL6.510 TACAAAGAACTCAAACAAATCAGCAAGAACAAAAACAATCCCAACAAAATGTTG GACAAAGACATGAATAGACAATTCTCGAAAGAAGATGTACAAATGGCT (SEQ ID NO: 233) 228 HGL6.512 AGAGAAATGCAAATCAAAACCACAATGGAATACCATCTCACGCCAGTCAGAATG GCAATTATTAAAAAATCACAACAATTAATGATGGCAAGGCTGTGG (SEQ ID NO:  234) 229 HGL6.513 GTAAACAAACAATCAAGCAAGTAAGAACAGAAATAACAGCATTTGGCTTTTGAG TTAATGACAAGAACACTCGGCATGGGAGCCTGGGTGAGCAAATCACAGATCTTC (SEQ ID NO: 235) 230 HGL6.514 GAATCAACCCGAGCGGAAAGGAATGGAATGGAATGGAATCAACACGAATGGAA TGGAACGGAATGGAATGGGATGGGATGAAATGGAATGG (SEQ ID NO: 236) 231 HGL6.516 AGCAACTTCAGCAAAGTCTCAGGAGACAAAATCAATGTACAAAAATCACAAGCA TTCTTATACACCAATAACAGACAAACAGAGAGCC (SEQ ID NO: 237) 232 HGL6.520 AAGAAATGGAATCGAAGAGAATGGAAACAAACGGAATGGAATTGAATGGAATG GAATTGAATGGAATGGGA (SEQ ID NO: 238) 233 HGL6.522 GACATGCAAACACAACACACAGCACACATGGAACATGCATCAGACATGCAAACA CAACACACATACCACACATGGCATATGCATCAGACGTGCCTCACTAC (SEQ ID NO: 239) 234 HGL6.528 TACAGATAAGAAAATTGAGACTCAAGAGTATTACATAAATTGTTTCAGCTACCAC AGCAAAAAATGGTATGGTTGGGAATCAAGCTCAGGG (SEQ ID NO: 240) 235 HGL6.529 AAAGGAATGCACTCGAATGGAATGGACTTGAATGGAATGTCTCCGAATGGAACA GACTCGTATGAAATGGAATCGAATGGAATGGAATCAAATGGAATTGATTTGAGT GAAATGGAATCAAATGGAATGGCAACG (SEQ ID NO: 241) 236 HGL6.530 TGAAACAAATGATAATGAAAATACAACATACCAAACATACGAGATACAGTAAAA GCAGTACTAAGATGCAAGTATATATTGCTACAAGTGCCTAC (SEQ ID NO: 242) 237 HGL6.531 GGAACAAAATGAAATCGAACGGTAGGAATCGTACAGAACGGAAAGAAATGGAA CGGAATGGAATGCACTCGAATGGAAAGGAGTCCAAT (SEQ ID NO: 243) 238 HGL6.532 AAATTGATTGAAATCATCATAAAATGGAATCGAAGGGAATCAACATCAAATGGA ATCAAATGGAATCATTGAACGGAATTGAATGGAATCGTCAT (SEQ ID NO: 244) 239 HGL6.533 AGAAAGGATTCGAATGGAATGAAAAAGAATTGAATGGAATAGAACAGAATGGA ATCAAATCGAATGAAATGGAATGGAATAGAAAGGAATGGAATG (SEQ ID NO: 245) 240 HGL6.534 AGAATGGAAAGCAATAGAATGGAACGCACTGGATTCGAGTGCAATGGAATCAAT TGGAATGGAATCGAATGGAATGGATTGGCA (SEQ ID NO: 246) 241 HGL6.535 AACACCAAACGGAAAAAAACGGAATTATCGAATGGAATCGAAGAGAATCTTCG AACGGACCCGAATGGGATCATCTAATGGAATGGAATGGAATAATCCATGG (SEQ ID NO: 247) 242 HGL6.536 AATGGAGACTAATGTAATAGAATCAAATGGAATGGCATCGAATGGAATGGACTG GAATGGAATGTGCATGAATGGAATGGAATCGAATGGATTG (SEQ ID NO: 248) 243 HGL6.539 TGGGATATGGGTGAAAGAACAAGTTTGCAGAAAAGATACAGTGAATTATGGACC ATGAGTTCGGGAAAGAAGGGTAGGACTGCG (SEQ ID NO: 249) 244 HGL6.540 AAATCGAATGGAACGCAATAGAATAGACTCGAATGTAATGGATTGCTATGTAAT TGATTCGAATGGAATGGAATCGACTGGAATGCAATCCAATGGAATGGAATGCAA TGCAATGGAATGGAATCGAACGGAATGCAGTGGAAGGGAATGG (SEQ ID NO:  250) 245 HGL6.541 AATCAACAAGGAACTGAAACAAGTAAACAAGAAAACAAATAACACCATAAAAC ATGGGCAAAGGACATAAACAGACATTTTTCAAAAAAGACATACAAATGGCCGAG (SEQ ID NO: 251) 246 HGL6.542 AATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATCGAAGA GAATCATCGAATGGACCCAGGCTGGTCTTGAACTCC (SEQ ID NO: 252) 247 HGL6.545 ATTGAATGGGCTAGAATGGAATCATCTTTGAACGGAATCAAAGGGAATCATCAT CGAATGGAATCGAATGGAAATGTCAACG (SEQ ID NO: 253) 248 HGL6.547 AATGGACTCGAATGGAATCAACATCAAATGGAATCAAGCGGAATTATCGAATGA AATCGAAGAGAATCATCGAATGGACTCGAAAGGAATCATCTAATGGAATGGAAT GGAATAATCCATGGACTCGAATGCAATCATCATCG (SEQ ID NO: 254) 249 HGL6.549 ACAGACAGAGATTTAAAACAATAAACAAGCAGTAAGCAAACACAGATAACAAA ATGACATGATCCAACAAATACTCAGAAGGAGACTTAGAAATGAATTGAGGGTC (SEQ ID NO: 255) 250 HGL6.553 AATGTAATCCAGCATATAAACAGAGCCAAAGACAAAAACCACATGATTATCTCA ATAGATGCAGAAAAAGCCTTTGACAAAATTCAACAACCCTTCATGCTAAAAACT CTCAATAAATTAGGTATTGATGGGACG (SEQ ID NO: 256) 251 HGL6.555 AAACGGAAAAAAACGGAATTATTGAATGGAATCGAAGAGAATCTTCGAACGGA CCCGAATGGAATCATCTAATGGAATGGAATGGAATAATCCATGG (SEQ ID NO:  257) 252 HGL6.557 HGL6.1238 GCTCAAGGAAATAAAATAGGACACAAAGAAATGGAAAAACATTCCATACTCATG GATAGAAAGAATCAATATCATGAAATGGCC (SEQ ID NO: 258) 253 HGL6.560 ACTCGAGTGGAATTGACTGTAACAAAATGGAAAGTAACGGATTGGAATCGAATG GAACGGAATGGAATGGAATGGACAT (SEQ ID NO: 259) 254 HGL6.561 TACAAACTTTAAAAAATGATCAACAGATACACAGTTAGCAAGAAAGAATTGAGG GCAAAGAATATGCCAGACAAACTCAAGAGGAAGATGATGGTAGAGATAGGTCA CATTGGAGTGTCA (SEQ ID NO: 260) 255 HGL6.562 HGL6.154, GGAATCGAATGGAATCAATATCAAACGGAAAAAAACGGAATTATCGAATGGAAT HGL6.114 CGAAGAGAATCATCGAATGGACC (SEQ ID NO: 261) 256 HGL6.564 AACGGAATCAAACGGAATTATCGAATGGAATCGAAAAGAATCATCGAACGGACT CGAATGGAATCATCTAATGTAATGGAATGGAAGAATCCATGGACTCGAATG (SEQ ID NO: 262) 257 HGL6.565 GGAAATAACAGAGAACACAAACAAATGGGAAAACATTCCATGTTCATGGATAGG AAGAATCAATATTGTGAAAATGGCCATACT (SEQ ID NO: 263) 258 HGL6.570 AACGGAAAAAAACGGAATTATCGAATGGAATCGAAGAGAATCATCGAATGGAC CAGAATGGAATCATCTAATGGAATGGAATGGAATAATCCATGGACTCGAATG (SEQ ID NO: 264) 259 HGL6.581 CAACATCAAACGGAAAAAAACGGAATTATGGAATGGAATCGAAGAGAATCATC GAATGGACCCGAATGGAATCATCTGAAATATAATAGACTCGAAAGGAATG (SEQ ID NO: 265) 260 HGL6.589 ATGGAATCGAATGGAATGGACTGGAATGGAATGGATTCGAATGGAATCGAATGG AACAATATGGAATGGTACCAAATG (SEQ ID NO: 266) 261 HGL6.595 HGL6.1293 GAATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATCGAAG AGAATCATCGAATGGACC (SEQ ID NO: 267) 262 HGL6.606 AAGGAATTTAAGCAAATCAACAAGCAAAACCAAAATAATCCCATTAAAAAGTGG GTAAAGGACATGAATACACACTTGTCAATAGAGGACATTCAAGTGGCCAAC (SEQ ID NO: 268) 263 HGL6.608 AAATGGACTCGAATGGAATCATCATAGAATGGAATCGAATGCAATGGAATGGAA TCTTCCGGAATGGAATGGAATGGAATGGAATGGAG (SEQ ID NO: 269) 264 HGL6.609 GAATCANCNNNNNNNGGAATCGAATGGAATCAACATCAAATGGAATCAAATGG AATCATTGAACGGAATTGAATGGAATCGTCAT (SEQ ID NO: 270) 265 HGL6.610 AGCAACTTCAGCAAAGTCTCAGGATACAAAATCAATGTACAAAAATCACAAGCA TTCTTATACACCAATAACAGACAAACAGAGAGCCAAAA (SEQ ID NO: 271) 266 HGL6.611 TATGCAAATCAATAAACATAATCCATCACATAAACAGAAACAAAGACAAAATGA CATGATTATCTCAATAGATGCAGAAAAGGCC (SEQ ID NO: 272) 267 HGL6.615 AGTAAATCACCATAAAGAAGGTAAGAGTTCATTCACAAAAACAACAAACTGAAG AATCAGGCCATAGTA (SEQ ID NO: 273) 268 HGL6.617 AGAAACAGAAAACAGTCAAACCAATGGGCAATCCATATCAGATGCAGTATTATG AACAGAAGTGTAAAGAATGCACCAGGCACAATGGC (SEQ ID NO: 274) 269 HGL6.619 AGGAAAAACAACAACAACAACAGGAAAACAACCTCAGTATGAAGACAAGTACA TTGATTTATTCAACATTTACTGATCACTTTTCAGGTGGTAGGCAG (SEQ ID NO: 275) 270 HGL6.623 GATTGGAACGAAATCGAATGGAACGGAATAGAATAGACTCGAATGTAATGGATT GCTATGTAATTGATTCGAATGGAATGGAATCGAATGGAATGCAATCCAATGGAA TGGAATGCAATGCAATGGAATGG (SEQ ID NO: 276) 271 HGL6.624 AACATATGGAAAAAAACTCAACATCACTGATCATTAGAGAAATGCAAATCAAAA CCACAATGAGATACCATCTCACGCCAGTCAGAATGGCG (SEQ ID NO: 277) 272 HGL6.625 ATGGAATGGAATAATCAACGTACTCGAATGCAATCATCATCGTATAGAATCGAA TGGAATCATCGAATGGACTCGAATGGAATAATCATTGAACGGAGTCGAATGGAA TCATCATCGGATGGAAAC (SEQ ID NO: 278) 273 HGL6.627 AAANAANTCNAATGGAATCNNTGNCGAATGGAATGGAATGGAATCGAANAATT GAATTGNNNANAATCNNANGNAANCNTTGNATGGGCTCAAAT (SEQ ID NO: 279) 274 HGL6.629 AGAAAAGATAACTCGATTAACAAATGAACAAACACCTGAATACACAAGTCTCAA AAGAAGACATAAAAATGGCCAAC (SEQ ID NO: 280) 275 HGL6.632 ATGGAATCAACATCAAACGGAATCACACGGAATTATCGAATGGAATCGAAAAGA ATCATCGAACGGACTCGAATGGAATCATCTAATGGAATGGAATGGAAG (SEQ ID NO: 281) 276 HGL6.633 HGL6.1135 AATGGAATCAACATCAAACGGAATCAAGCGAAATTATCGAATGGAATCGAAGAG AATCATCGAATGGACTCGAATGGAATCATCTAATGGAATGGAATGGGAT (SEQ ID NO: 282) 277 HGL6.634 AAACACAGTACAAATACTAATTCAAATCAAACTTACTCAAAGTCATAATCAAAC ATGCCAGACGGGCTGAGGGGCAGCATTA (SEQ ID NO: 283) 278 HGL6.638 AACCACTGCTCAAGGAAATAAGAGAGAACACAAACAAATGAAAAAACATTCCA TGCTCATGGATAGGAAGAATCAG (SEQ ID NO: 284) 279 HGL6.641 GGAATCGAGTGGAATCATCGAAAGAAATCGAATGGAATCATTGTCGAATGGAAT GGAATGGAATCAAAGAATGGAATCGAAGGGAATCATTGGATGGGCT (SEQ ID NO: 285) 280 HGL6.642 AAAGAAAGACAGAGAACAAACGTAATTCAAGATGACTGTTTACATATCCAAGAA CATTAGATGGTCAAAGACTTTAAGAAGGAATACATTCAAAGGCAAAAAGTCACT TACTGATTTTGGTGGAGTTTGCCACATGGAC (SEQ ID NO: 286) 281 HGL6.645 AAGATAGAGTTGAAACAGTGGACAATTAAAGAGTAATTTGGAAGAATGGTGAAA TTACAGCCATGCTTTGAATCAGGCGGGTTCACTGGC (SEQ ID NO: 287) 282 HGL6.646 AAGAGTATCAACAGTAAATTACATTAGCAGAAGAATCAACAAACATGAAAATAG AAATTATGGTAGCCAAAGAACAG (SEQ ID NO: 288) 283 HGL6.647 GAAAGGAATCATCATTGAATGCAATCACATGGAATCATCACAGAATGGAATCGT ACGGAATCATCATCGAATGGAATTGAATGGAATCATCAATTGGACTCGAATGGA ATCATCAAATGGAATCGATTGGAAGTGTCAAATGGACTCG (SEQ ID NO: 289) 284 HGL6.651 CAGCGCACCACAGCACACACAGTATACACATGACCCACAATACACACAACACAC AACACATTCACACACCAC (SEQ ID NO: 290) 285 HGL6.655 GCAAACAGAATTCAACACTACATTAGAACGATCATTCATCACGACCTAGTAGGA TGTTTTTCCTGGGATGCAAGGATGGTTCAACAT (SEQ ID NO: 291) 286 HGL6.656 CAATCAAAACAGCAATGAGATACCATTTTACACCAATCAAAATGGCTACTAAAA AGTCAAAAGCAAATGCC (SEQ ID NO: 292) 287 HGL6.658 HGL6.830 AGAACCATATTGAAGAGACAGAGTGATATATAAAACTGCTAACTCAAGCAGCAC AAGAATTAAATGAATACCAAGAAAATACTTGGCCAG (SEQ ID NO: 293) 288 HGL6.660 TGGAATAGAATGGAATCAATGTTAAGTGGAATCGAGTGGAATCATCGAAAGAAA TCGAATGGAATCATTGTCGAATGGTATGGAATGGAATCA (SEQ ID NO: 294) 289 HGL6.661 AATGGAATGGAATCATCGCATAGAATNGAATGGAATTATCATCGAATTGAATCG AATGGTATCAACATCAAACGGAAAAAAACGGAAATATCGAANGGAATCGAAGA GAATCATCGAACGGACC (SEQ ID NO: 295) 290 HGL6.662 ACATACGCAAATCAATAAACATAATCCATCACATAAACAGAACCAAAGACAAAA ATCACATGATTATCTCAATAGATGCAGAAAAGGCCTTCGAC (SEQ ID NO: 296) 291 HGL6.663 AAAAAATGTTCAACATCACTAGTCAGCAGAGAAATGCAAATCAAAATCACAATG AGATAACTTCTCACACCAGACAGCATGGC (SEQ ID NO: 297) 292 HGL6.668 GAAAAACAAAACAAAACAAACAAACAAACAATCAAAAAAGTGGTAGCAGAAAC CAGAAAGTCCATGTATATAGCTAATTGGCCTGGTTGT (SEQ ID NO: 298) 293 HGL6.671 AACAGCAATGACAATGATCAGTAACAACAAGACTTTTAACTTTGAAAAAATCAG GACC (SEQ ID NO: 299) 294 HGL6.672 AAGAGCCTGAATAGCTAAAGTGATCATAAGCAAAAAGAACAAAGTCGGAAGCA TCACATTACCTGACTTCAAACTATACTCAAAGGCTATG (SEQ ID NO: 300) 295 HGL6.675 AAAAGGAAATACAAGACAACAAACACAGAAACACAACCATCGGGCATCATGAA ACCTCGTGAAGATAATCATCAGGGT (SEQ ID NO: 301) 296 HGL6.677 AAGCAAAGAAAGAATGAAGCAGCAAAAGAACGAAAGCAGGAATTTATTGAAAA CCAAAGTACACTCCACAGTATGGGAGCGGACCCGAGCA (SEQ ID NO: 302) 297 HGL6.679 GCAAATGATTATAAGTGCTGTTATAGAAACATTCAAAGACCAGAAAAGGACCAC AATGGCTGACCAC (SEQ ID NO: 303) 298 HGL6.681 AGAGCAGAAACAAATGGAATTGAAATGAAGACAACAATCAAAAGCATCAATGA AATGAAAAGTTGGGTTTTGGAAGAGAGAAACAAT (SEQ ID NO: 304) 299 HGL6.683 ACACAAACACACACACACACACACACACACACACACACACACACACACACACAC ACACACACACACATAC (SEQ ID NO: 305) 300 HGL6.686 AACAAACAAATGAGATGATTTCAGATAGTGATAAACACTATAACATAATTAATT CGTGCCAATCAGAGCATAACAGTGGTGTGGTGGCTGTGGAACAGATAGCAGAC (SEQ ID NO: 306) 301 HGL6.688 AATGGAATCGAGTGGAATGGAAGGCAATGGAATAGAATGGAATGGAATCGAAA GGAACGGAATGGAATGGAATGGAATG (SEQ ID NO: 307) 302 HGL6.689 AGCAGTGCAAGAACAACATAACATACAAGTAAACAAACACATGGGGCCAGGTA ATAAAAAGTCAGGCTCAAGAGGTCAG (SEQ ID NO: 308) 303 HGL6.690 AGAAATGGAATCGGAGAGAATGGAAACAAATGGAATGGAATTGAATGGAATGG AATTGAATGGAATGGGAACG (SEQ ID NO: 309) 304 HGL6.694 GCACTAGTCAGATCAAGACAGAAAGTCAACGAACAAAGAACAGACTTAAACTAC ACTCTAGAACAAATGGACCTA (SEQ ID NO: 310) 305 HGL6.704 AAGAGAACTGCAAAACACTGCTCAAAGAAATCAGAGATGACAAAAACACATGG AAAAACGTTTCATGCTCATGGATTGGAAGACTTA (SEQ ID NO: 311) 306 HGL6.705 AATCAACACGAATAGAATGGAACGGAATGGAATGGAATGGAATGGAATGGAAT GGAGTGGAATGGAACAGAATGGAGTGGAAT (SEQ ID NO: 312) 307 HGL6.707 AACATCAAACGAAATCAAACGGAATTATCAAATTGAATCGAAGAGAATCATCGA ATTGCCACGAATGCAACCATCTAATGGTATGGAATGGAATAATCCATGGACCCA GATG (SEQ ID NO: 313) 308 HGL6.714 CGGAATTATCATCGAATGTAATCGAATGGAATCAACATCAAACGGAAAAAAACG GAATTATCGAATGGAATCGAAGAGAATCATCGAATGGACC (SEQ ID NO: 314) 309 HGL6.719 TGGACACACACGAACACACACCTACACACACGTGGACACACACGGACACATGGA CACACACGAACACATGGACACACACACGGGGACACACACAGACACACACAGAG ACACACACGGACACATGG (SEQ ID NO: 315) 310 HGL6.720 HGL6.1044 AGCAACTTCAGCAAAGTCTCAGGATACAAAATCAATGTGCAAAAATCACAAGCA TTCTTATACACCAATAACAGACAAACAGAGAGCC (SEQ ID NO: 316) 311 HGL6.721 HGL6.1020 AAAATCAATATGAAAACAAACACAAGCAGACAAAGAAAATTGGGCAAAAGGTT TGAGCAGACACTTCACCAAAGAAGTACAAATGGCAAATCAGCA (SEQ ID NO: 317) 312 HGL6.724 ATCAAACGGAATCAAACGGAATTATCGAATGGAATCGAAGAGAATCATCGAATG GACTCGAATGGAATCATCTAATGGAATGGAATGGAAGAATCCATGG (SEQ ID NO: 318) 313 HGL6.725 AACAGATTTAAACAAACCAACAAGCAAAAAACGAACAACTCCATTCAAACATGG ACAAAAGACACGAACAGACACTTTTCAAAGAAGACATACATGTGGCC (SEQ ID NO: 319) 314 HGL6.726 AAATGGAATGGAATGCACTTGAAAGGAATAGACTGGAACAAAATGAAATCGAA CGGTAGGAATCATACAGAACAGAAAGAAATGGAACGGAATGGAATG (SEQ ID NO: 320) 315 HGL6.727 ACCACACACAAAATACACCACACACCACACACACACCACACACTATACACACAC CACACACCACACAC (SEQ ID NO: 321) 316 HGL6.728 AAAGAAATAGAAGGGAGTTGAACAGAATCGAATGGAATCGAATCAAATGGAAT CGAATGGCATCAAATGGAATCGAATGGAATGTGGTGAAGTGGATTGG (SEQ ID NO: 322) 317 HGL6.729 GGAATCATCATAAAATGGAATCGAATGGAATCATCATCAAATGGAATCAAATGG AATCATTGAACGGAATTGAATGGAATCGTCAT (SEQ ID NO: 323) 318 HGL6.730 TGGAATGGAATGGAATGAAATAAACACGAATAGAATGGAACGGAATGGAACGG AATGGAATGGAATGGAATGGAAAG (SEQ ID NO: 324) 319 HGL6.731 AAGAATTGGACAAAACACACAAACAAAGCAAGGAAGGAATGAAAGGATTTGTT GAAAATGAAAGTACACTCCACAGTGTGGGAGCAG (SEQ ID NO: 325) 320 HGL6.732 TAATCAGCACAATCAACTGTAGTCACAAAACAAATAGTAACGCAATGATAAAGA AACAGAGAACTAGTTCAAATAAACATGATAAGATGGGG (SEQ ID NO: 326) 321 HGL6.733 AAGCGGAATTATCAAATGGAATCGAAGAGAATGGAAACAAATGGAATGGAATT GAATGGAATGGAATTGAATGGAATG (SEQ ID NO: 327) 322 HGL6.734 AAGCAACTTCAGCAAAGTCTCAGGACACAAAATCAATATGCGAAAATCACAAGC ATTCCTATACACCAATAATAGACAAACAGAGAGCCAAATCATG (SEQ ID NO: 328) 323 HGL6.736 TTCACAGCAGCATTACGCACAATAGCCAGAAGGTGGGAACAGACAAAATGCCTT TTGATGGG (SEQ ID NO: 329) 324 HGL6.738 AGACCCTAATATCACAGTTAAACGAACTAGAGAAGGAAGAGCAAACAAATTCAA AAGCTAGCGGAAAGCAAGAAATAACTAAGACCAG (SEQ ID NO: 330) 325 HGL6.739 TAAAAGTGTGCTCAACATCATTGATCATCAGAGAAATGCAAATCAAAACTACAA TGAGATATCATCTCATCCCAGTCAAAGTGGCT (SEQ ID NO: 331) 326 HGL6.740 ACTTGAATCGAATGGAAAGGAATTTAATGAACTTAAATCGAATGGAATATAATG GTATGGAATGGACTCATGGAATGGAATGGAAAGGAATC (SEQ ID NO: 332) 327 HGL6.742 TGGAATCATCATCGAAAGCAAGCGAATGGAATCATCAAATGGAAACGAATGGAA TCATCGAATGGACTCGGATGGAATTGTTGAATGGACT (SEQ ID NO: 333) 328 HGL6.743 TGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATCGAAGAGA ATCATCGAATGGACC (SEQ ID NO: 334) 329 HGL6.745 TAAGTGAATTGAATAGAATCAATCTGAATGTAATGAAATGGAATGGAACGGAAT GGAATGGAATGGAATGGAATGGAATGGAATGG (SEQ ID NO: 335) 330 HGL6.747 AGGAAAATTTAATCAGCAGGAATAGAAACACACTTGAGAAATCCATGTGGAATG AAAAGAGAATGGCTGAGCAGCAACAGATTGTCAAAAAGGAAATC (SEQ ID NO: 336) 331 HGL6.749 HGL6.897 AACATCAAACGGAAAAAAAACGGAATTATCGAATGGAATCGAAGAGAATCATC GAATGGACC (SEQ ID NO: 337) 332 HGL6.756 GAAAATGAACAATATGAACAAACAAACAAAATTACTACCCTTACGAAAGTACGT GCATTCTAGTATGGTGACAAAAAGGAAA (SEQ ID NO: 338) 333 HGL6.757 AGAAAACACACAGACAACAAAAAACACAGAACGACAATGACAAAATGGCCAAG C (SEQ ID NO: 339) 334 HGL6.758 HGL6.1040 AGCAACTTCAGCAAAGACTCAGGATACAAAATCAATGTGCAAAAATCACAAGCA TTCTTATACACCAATAACAGACAGAGAGCCAAAT (SEQ ID NO: 340) 335 HGL6.759 TGACATGCAAGAAATAAGGAAGTGCAAAAACAAACAAACAAACAACAACAACA ACAACAACAACAACAACAAAAAACAGTCCCAAAAGGATGGGCAG (SEQ ID NO: 341) 336 HGL6.760 TAATTGAGAATAAGCATTCCAGTGGAAAAAAAACTAAACAATTTGTTGTAAAAC ATCCTTAAAAGCATCAGAAAGTTAATACAGCAATGAAGAATTACAGGACCAAAT TAAGAATGGTATGGAAGCCTGTTA (SEQ ID NO: 342) 337 HGL6.762 TATCATCGAATGGAATCGAATGGAATCAACATCAAACGGAAAAAAACGGAATTA TCGAATTGAATCGAAGAGAATCATCGAATGGACC (SEQ ID NO: 343) 338 HGL6.764 GAATGGAATCAAATAGAATGGAATCGAAACAAATGGAATGGAATGGAATGGGA GCTGAGATTGTGTCACTGCAC (SEQ ID NO: 344) 339 HGL6.765 AGCAAAACAAACACAATCTGTCGTTCATGGTACTACGACATACTGGGAGAGATA TTCAAATGATCACACAAAACAACATG (SEQ ID NO: 345) 340 HGL6.766 AAGGATTCGAATGGAATGAAAAAGAATTGAATGGAATAGAACAGAATGGAATC AAATCGAATGAAATGGAGTGGAATAGAAAGGAATGGAATG (SEQ ID NO: 346) 341 HGL6.768 AACGGAATCAAACGGAATTATCGAATGNNNTNNAAGAGAATCATCGAACGGACT CGAATGGAATCATCTAATGGAATGGAATGGAAGAATCCATGGACTCGAATGCAA TCATCATCGAATGGAATCGAACGGAATCATCGAATGGCC (SEQ ID NO: 347) 342 HGL6.771 AATCAACTAGATGTCAATGGAATGCAATGGAATAGAATGGAATGGAATTAACAC GAATAGAATGGAATGGAATGGAATGGAATGG (SEQ ID NO: 348) 343 HGL6.772 TGTAACACTGCAAACCATAAAAACCGTAGAAGAAAACCTAGACAATACTATTCA GGACATAGGCATGGGCAAAGAC (SEQ ID NO: 349) 344 HGL6.773 AATGGACTCGAATGGAATAATCATTGAACGGAATCGAATGGAATCATCATCGGA TGGAAATGAATGGAATCATCATCGCATGGAATCG (SEQ ID NO: 350) 345 HGL6.776 GAATGGAATGATACGGAATAGAATGGAATGGAACGAAATGGAATTGAAAGGAA AGGAATGGAATGGAATGGAATGG (SEQ ID NO: 351) 346 HGL6.777 AAAAATGACCAGAGCAATAGAATGCATTGACCAGATAAAGACCTTCACGTATGT TGAACTAAAATGTGTGGTGCAGGTG (SEQ ID NO: 352) 347 HGL6.781 AATCATCATCGAATGGAATCGAATGGTATCATTGANTGNAATCGAATGGAATCA TCATCANATGGAAATGAATGGAATCGTCAT (SEQ ID NO: 353) 348 HGL6.785 ACAAAATCAAACTAACCTCGATAAGAATGCAAGTGAATCAAAATGAGTTTCAAG GGGTTGTGGCTAGTACACGCTTTCTACAGCTG (SEQ ID NO: 354) 349 HGL6.787 GAATCAAATCAATGGAATCAAATCAAATGGAATGGAATGGAATTGTATGGAATG GAATGGCATGG (SEQ ID NO: 355) 350 HGL6.789 TAATGCAGTCCAATAGAATGGAATCGAATGGCATGGAATATAAAGAAATGGAAT CGAAGAGAATGGGAACAAATGGAATGGAATTGAGTGGAATGGAATTGAATGGA ATGGGAACGAATGGAGTG (SEQ ID NO: 356) 351 HGL6.792 TGAATAGACACACAGACCAATGGAACAGAATAGAGAACACAGAATAAATCTGC ACACTTATAGCCAGCTGATTTTTGACAAATTTGCCAAG (SEQ ID NO: 357) 352 HGL6.797 HGL6.810, AACATCNNACGGAAAAAAACGGAATTATCGAATGGAATCGAAGAGAATCATCG HGL6.1172, AATGGACC (SEQ ID NO: 358) HGL6.1223 353 HGL6.801 GCCAACAATCATATGAGAAAAAGCTCAACATCACTGATCATTTCAGGAATGCAA ATCAAAACCACAATGAGATACTATCACACATCAATCAGAATGGCT (SEQ ID NO: 359) 354 HGL6.802 HGL6.118, GAATCGAATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATC HGL6.590, GAAGAGAATCATCGAATGGACC (SEQ ID NO: 360) HGL6.1051, HGL6.1170, HGL6.1248, HGL6.1372 355 HGL6.804 AATCAAATGGAATGAAATCGAATGGAATTGAATCGAATGGAATGCAATAGAATG TCTTCAAATGGAATCGAATGGAAATTGGTGAAGTGGACGGGAGTG (SEQ ID NO: 361) 356 HGL6.805 TAACAGTACCAAAAAACAGTCATAATCTTCAAGAGCTTAAATTTAGCATGAAAG GAAGACATTCATCAAAGAATCACACAAAGGAATGTAAAATTAAATGGAGATTAG TGCCAGGAAAGAGC (SEQ ID NO: 362) 357 HGL6.808 TAATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGCAATCGAAGA GAATCATCGAATGGACC (SEQ ID NO: 363) 358 HGL6.813 AGCAACTTCAGCAAAGTCTCAGCATACAAAATCAATGTGCAAAAATCACACGCA TTCCTATACACCAATAACAGACAAACAGAGAGCC (SEQ ID NO: 364) 359 HGL6.815 GAATCAAATGGAATGGACTGTAATGGAATGGATTCGAATGGAATCGAATGGAGT GGACTCAAATGGAATG (SEQ ID NO: 365) 360 HGL6.816 AACAAGTGGACGAAGGATATGAACAGACACTTCTCAAGACATTTATGCAGCCAA CAGACACACGAAAAAATGCTCATCATCACTGGCCATCAG (SEQ ID NO: 366) 361 HGL6.819 AAACACACAAAGCAACAAAAGAACGAAGCAACAAAAGCATAGATTTATTGAAA TGAAAGTACATTCTACAGAGTGGGGGCAGGCT (SEQ ID NO: 367) 362 HGL6.820 ATACAACTAAAGCAAATATAAGCAACTAAAGCAACAGTACAACTAAAGCAAAA CAGAACAAGACTGCCAGGGCCTAGAAAAGCCAAGAAC (SEQ ID NO: 368) 363 HGL6.822 GCAATCGAATGGAATGGAATCGAACGGAATGGAATAAAATGGAAGAAAACTGG CAAGAAATGGAATCG (SEQ ID NO: 369) 364 HGL6.825 AGCAGCCAACAAGCATATGAAATAATGCTCCACAACACTCATCATCAGAGAAAT GCAAATCAAAACCAAAAT (SEQ ID NO: 370) 365 HGL6.826 TGGAACCGAACAAAGTCATCACCGAATGGAATTGAAATGAATCATAATCGAATG GAATCAAATGGCATCTTCGAATTGACTCGAATGCAATCATCCACTGGGCTT (SEQ ID NO: 371) 366 HGL6.827 HGL6.829 AACGGAATCACGCGGAATTATCGAATGGAATCGAAGAGAATCATCGAATGGACT CGAATGGAATCATCTAATGGAATGGAATGG (SEQ ID NO: 372) 367 HGL6.830 AGAACCATATTGAAGAGACAGAGTGATATATAAAACTGCTAACTCAAGCAGCACAAGAATTA AATGAATACCAAGAAAATACTTGGCCAG (SEQ ID NO: 373) 368 HGL6.831 AAAACAAACAACAACGACAAATCATGAGACCAGAGTTAAGAAACAATGAGACC AGGCTGGGTGTGGTG (SEQ ID NO: 374) 369 HGL6.833 AATCGAAAGGAATGCAATATTATTGAACAGAATCGAAAAGAATGGAATCAAATG GAATGGAACAGAGTGGAATGGACTGC (SEQ ID NO: 375) 370 HGL6.836 AAGGAATCGAATGGAAGTGAATGAAATTGAATCAACAGGAATGGAAGGGAATA GAATAGACTGTAATGGAATGGACTCG (SEQ ID NO: 376) 371 HGL6.837 AATGGACTCGAATGAAATCATCATCAAACGGAATCGAATGGAATCATTGAATGG AATGGAATGGAATCATCATGGAATGGAAACG (SEQ ID NO: 377) 372 HGL6.838 TTGACCAGAACACATTACACAATGCTAATCAACTGCAAAGGAGAATATGAACAG AGAGGAGGACATGGATATTTTGTG (SEQ ID NO: 378) 373 HGL6.839 AACCCGAGTGCAATAGAATGGAATCGAATGGAATGGAATGGAATGGAATGGAA TGGAATGGAGTC (SEQ ID NO: 379) 374 HGL6.843 AAGAGTATTGAAGTTGACATATCTAGACTGATCAAGAACAAAGACAAAAGGTAC AGATTATCAAGAAAATGAGCGGGCAAAGCAAGATGGCC (SEQ ID NO: 380) 375 HGL6.847 GAATGGAATTGAAAGGAATGGAATGCAATGGAATGGAATGGGATGGAATGGAA TGCAATGGAATCAACTCGATTGCAATG (SEQ ID NO: 381) 376 HGL6.849 GAAAAAAACGGAATTATCNAATTGAATCNAATANAATCATCNNNNNGACCANA NTGGAATCATCTAATGNAATGNAATGGAATAATCCATGGACTCNAATG (SEQ ID NO: 382) 377 HGL6.850 GAAAAAAACGGAATTATCGAATTGAATCGAATAGAATCATCGAACGGACCAGAA TGGAATCATCTAATGGAATGGAATGGAATAATCCATGGACTCGAATG (SEQ ID NO: 383) 378 HGL6.853 AACCACTGCTTAAGGAAATAAGAGAGAACACAAACAAATGGAAAAACGTTCCAT GCTCATGGATAGGAGAATCAATATCGTGAAAATGGCC (SEQ ID NO: 384) 379 HGL6.854 TATCGAATGGAATGGAAAGGAGTGGAGTAGACTCGAATAGAATGGACTGGAATG AAATAGATTCGAATGGAATGGAATGGAATGAAGTGGACTCG (SEQ ID NO: 385) 380 HGL6.855 GTATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATCATCTAATGGA ATGGAATGGAATAATCCATGGACTCGAATG (SEQ ID NO: 386) 381 HGL6.856 TAAATGGAGACATCATTGAATACAATTGAATGGAATCATCACATGGAATCGAAT GGAATCATCGTAAATGCAATCAAGTGGAATCAT (SEQ ID NO: 387) 382 HGL6.857 GAATGGAATTGAAAGGTATCAACACCAAACGGAAAAAAAAACGGAATTATCGA ATGGAATCGAAGAGAATCATCGAACGGACC (SEQ ID NO: 388) 383 HGL6.858 AGCAATTTCAGCAAAGTCTCAGGATACAAAATCAATGTACAAATTCACAAGCAT TCTTATGGACCAACAACAG (SEQ ID NO: 389) 384 HGL6.860 AACCAAATTAGACAAATTGGAAATCATTACACATAACAAAAGTAATAAACTGTC AGCCTCAGTAGTATTCATTGTACATAAACTGGCC (SEQ ID NO: 390) 385 HGL6.861 TATTTTACCAGATTATTCAAGCAATATATAGACAGCTTAAAGCATACAAGAAGAC ATGTATAGATTTACATGCAAACACTGCACCACTTTACATAAGGGACTTGAGCAC (SEQ ID NO: 391) 386 HGL6.863 GGAATCGAATGGCATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAAT CGAATGGAATCATC (SEQ ID NO: 392) 387 HGL6.864 AAACAAAACACAGAAATGCAAAGACAAAACATAAAACGCAGCCATAAAGGACA TATTTTAGATAACTGGGGAAATTTGTATGGGCTGTGT (SEQ ID NO: 393) 388 HGL6.866 HGL6.867 AGGAAAAGAAAGAAATAGAAAATGCGAAATGGTAAGAAAAAACAGCATAATAA ACATTTGTATGGTGTTGATGGACAATGCATT (SEQ ID NO: 394) 389 HGL6.869 AATGGAATCAACATCAAACGGAATCAAACGGAATTATCGAATGGAATCGAAGAG AATCATCGAACGGACTCGAATGGAATCATCTAATGGAATGGAATGGAAG (SEQ ID NO: 395) 390 HGL6.872 HGL6.1072, AATCGAATGGAATCAGCATCAAACGGAAAAAAACGGAATTATCGAATGGAATCG HGL6.1301 AAGAGAATCATCGAATGGACC (SEQ ID NO: 396) 391 HGL6.877 AAAGAAATGGAATCGAAGAGAATGGAAACAAATGGAATGGAATTGAATGGAAT GGAATTGAATGGAATGGGAACG (SEQ ID NO: 397) 392 HGL6.878 AGAAAGAATCAAGAGGAAATGCAAGAAATCCAAAACACTGTAACAGATATGAT GAATAATGAGGTATGCACTCATCAGCAGACTCGACAT (SEQ ID NO: 398) 393 HGL6.879 AAACGGAATTATNNANTGGANNNNAAGNNAATCATCGAACGGANNNNANNGGA ATCATNTNNNNGAANGGAATGGAACAATCCATGGTNTNNNN (SEQ ID NO: 399) 394 HGL6.882 HGL6.971 AGCAACTTCAGCAAAGTTTCAGGATACAAAATCAATGTGCAAAAATCACAAGCA TTCTTATACACCAACAACAGACAAACAGAGAGCC (SEQ ID NO: 400) 395 HGL6.884 AGACAGTCAGACAATCACAAAGAAACAAGAATGAAAATGAATGAACAAAACCT TCAAGAAATATGGGATTATGAAGAGGCCAAATGT (SEQ ID NO: 401) 396 HGL6.885 ATCATAACGACANGANCAAATTCACACACAACAATNNNNACNNNAAANNCAAA TGGGTTAAATNNTNCAATTAAAGGATGCAGACGGGCAAATTGGATA (SEQ ID NO: 402) 397 HGL6.891 ATCATAANGACAAGANCAAATTCACACACAACAATNNNNACNNNAAANNCAAA TGGGTTNAATGNTNCAATTAAAGGATGCAGACGGNCAAATTGGATA (SEQ ID NO: 403) 398 HGL6.895 GAATGGAATCGAATGGATTGATATCAACTGGAATGGAATGGAAGGGAATGGAAT GGAATGGAATTGAACCAAATGTNNNNGNCTTGAATGGAATG (SEQ ID NO: 404) 399 HGL6.898 GAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATCGAAGAGAAT CATCGAATGGACC (SEQ ID NO: 405) 400 HGL6.904 ATGGAATCAACATCAAACGGAATCAAACGGAATTATCGAATGGAATCAAAGAGA ATCATCGAACGGACTCGAATGGAATCATCTAATGGAATGGAATGGAAGAATCCA TGGACTCGAATGCAATCATCATCGAAT (SEQ ID NO: 406) 401 HGL6.905 GGAATGGAATGGAATGGAGCNGAATNGAANGGANNNNANTCAAATGGAATGC (SEQ ID NO: 407) 402 HGL6.906 AACATACGC AAATCAATAAATG TAATCCAGCATATAAACAGAACCAAAGACAA AAACCACATGATTATCTCAATAGATGCAGAAAAGGCC (SEQ ID NO: 408) 403 HGL6.911 AAACGATTGGACAGGAATGGAATCACCATCGAATGGAAACGAATGGAATCTTCG AATGGAATTGAATGAAATTATTGAACGGAATCAAATAGAATCATCATTGAACAG AATCAAATTGGATCAT (SEQ ID NO: 409) 404 HGL6.912 AAAAGATGCAAAAGTAGCAAATGCAATGTTAAAACAAGCAAAGAAAGAATCAG GTGGACCACATAGTGCAGTGCTTCTC (SEQ ID NO: 410) 405 HGL6.914 AACAATAAACAAACTCCAACTAGACACAATAGTCAAATTGCTGAAAATGAAATA TAAAGGAACAATCTCGATGGTAGCCCAAGGA (SEQ ID NO: 411) 406 HGL6.915 HGL6.916 AGTCAATAACAAGAAGACAAACAACCCAATTACAAAATGGGATATGAATTTAAT AGATGTTACTCCAAGGAAGATACACAAATGGCCAAC (SEQ ID NO: 412) 407 HGL6.919 AAAACACCTAGGAATACAGATAACAAGGGACATTAACTACCTCTTAAAGAGAAC TACAAACCACTGCTCAAGGAAATGAGAGAGGACACAAACACATGGAAAAACAT TCCATCCTCATGGATAGGAAGAATCAATATTGTGAAAATGGCC (SEQ ID NO: 413) 408 HGL6.921 GATATATAAACAAGAAAACAACTAATCACAACTCAATATCAAAGTGCAATGATG GTGCAAAATGCAAGTATGGTGGGGACAGAGAAAGGATGC (SEQ ID NO: 414) 409 HGL6.923 ACACATATCAAACAAACAAAAGCAATTGACTATCTAGAAATGTCTGGGAAATGG CAAGATATTACA (SEQ ID NO: 415) 410 HGL6.924 GGAATCATCATATAATGGAATCGAATGGAATCAACATCAAATGGAATCAAATGG AATCATTGAACGGAATTGAATGGAATCGTCAT (SEQ ID NO: 416) 411 HGL6.926 CCCAACTTCAAATTATACTACAAGGCTACAGTAATCAAAAAAGCATAGTACTATT ACAAAAACAGACACACAGGCCAATGGAATACAAT (SEQ ID NO: 417) 412 HGL6.927 AAACGCAGAAACAAATCAACGAAAGAACGAAGCAATGAAAGACAAAGCAACAA AAGAATGGAGTAAGAAAGCACACTCCACAAAGTGGAAGCAGGCTGGGACA (SEQ ID NO: 418) 413 HGL6.928 AACTAACACAAGAACAGAAAACCAAACATCACATGTTCTCACTCATAAGCGGGA GCTGAACAATGAGAACACACGGACACAGGGAGAGGAACATG (SEQ ID NO: 419) 414 HGL6.929 GCCACAATTTTGAAACAACCATAATAATGAGAATACACAAGACAACTCCAATAA TGTGGGAAGACAAACTTTGCAATTCACATCATGGC (SEQ ID NO: 420) 415 HGL6.933 AATGGAATCAACATCAAACGGAATCAAATGGAATTATCGAATGGAATCGAAGAG AATCATCGAATTGTCACGAATGGAATCATCTAATGGAATGGAATGGAATAATCC ATGGCCCCTATGC (SEQ ID NO: 421) 416 HGL6.934 HGL6.935 TAAACAGAACCAAAGACAAAAATCACATGATTATCTCAATAGATGCAGAAAAGG CC (SEQ ID NO: 422) 417 HGL6.937 ATCAACAGACAACAGAAACAAATCCACAAAGCACTTAGTTATTAGAACTGTCAT ACAGACTGTACAACAACCACATTTACCAT (SEQ ID NO: 423) 418 HGL6.938 AATGGACTCGAATGAAATCATCATCAAACAGAATCGAATGGAATCATCTAATGG AATGGAATGGCATAATCCATGGACTCGAATG (SEQ ID NO: 424) 419 HGL6.939 TAAAATGAAACAAATATACAACACGAAGGTTATCACCAGAAATATGCCAAAACT TAAATATGAGAATAAGACAGTCTCAGGGGCCACAGAG (SEQ ID NO: 425) 420 HGL6.940 AAAATACAGCGTTATGAAAAGAATGAACACACACACACACACACACACACAGA AAATGT (SEQ ID NO: 426) 421 HGL6.942 TACTCTCAGAAGGGAAGCAGATATTCAGCATAAATCATATTGTTTGTACAAAGA GTCTGGGCATGGTGAATGACACT (SEQ ID NO: 427) 422 HGL6.943 CAAACAAATAGGTACCAAACAAATAACAACATAAACCTGACAACACACTTATTT ACAAGAGACATCCCTTATATGAAAGGGTACAGAAAAGTCGATGGTAAGATGATG GGGAAAGGTATACCAACCACTAGCAGAAGG (SEQ ID NO: 428) 423 HGL6.944 TGGAATCGAATGGAATCAATATCAAACGGAAAAAAACGGAATTATCGAATGGAA TCGAAAAGAATCATCGAATGGGCCCGAATGGAATCATCT (SEQ ID NO: 429) 424 HGL6.945 ACAAATGGAATCAACAACGAATGGAATCGAATGGAAACGCCATCGAAAGGAAA CGAATGGAATTATCATGAAATTGAAATGGATG (SEQ ID NO: 430) 425 HGL6.947 GACAAGAGTTCAGAAAGGAAGACTACACAGAAATACGCATTTTAAAGTCACTGA CATGGAGATGACACTTAAAACCATGAACATGGATGGG (SEQ ID NO: 431) 426 HGL6.956 AAAATAAACGCAAATTAAAATCACAAGATACCAACACATTCCCACGGCTAAGTA CGAAGAACAAGGGCGAATGGTCAGAATTAAGCTCAAACCT (SEQ ID NO: 432) 427 HGL6.957 TAAACTGACACAAACACAGACACACAGATACACACATACATACAGAAATACACA TTCACACACAGACCTGGTCTTTGGAGCCAGAGATG (SEQ ID NO: 433) 0 HGL6.958 GATCAATAAATGTAATTCATCATATAAACAGAGAACTAAAGACAAAAACACATG ATTATCGCAATACATGCAGAAAAGGCC (SEQ ID NO: 434) 429 HGL6.962 AGGACATGAATAGACAATTCTCAAAAGAAGATACACAAGTGGCAAACAAACAC ATGAAAAAAGACTCAACATTAGTAATGACCATGGAAATGCAAATC (SEQ ID NO:  435) 430 HGL6.963 ACATCAAACGGAAAAAAACGGAATTATCGAATGGAATCGAAGAGAATCATCGA ATGGACC (SEQ ID NO: 436) 431 HGL6.965 AATGGACTCGAATAGAATTGACTGGAATGGAATGGACTCGAATGGAATGGAATG GAATGGAAGGGACTCG (SEQ ID NO: 437) 432 HGL6.966 AAGAAAGACAGAGAACAAACGTAATTCAAGATGACTGATTACATATCCAAGAAC ATTAGATGGTCAAAGACTTTAAGAAGGAATACATTCAAAGGCAAAACGTCACTT ACTGATTTTGGTGGAGTTTGCCACATGGAC (SEQ ID NO: 438) 433 HGL6.967 AACATAATCCATCAAATAAACAGAACCAAAGACAAAAACCACATGATTATCTCA ATAGATGCAGAAAAGGCCTTC (SEQ ID NO: 439) 434 HGL6.969 GAATGGAATCGAATGGAATGAACATCAAACGGAAAAAAACGGAATTATCGAAT GGAATCAAAGAGAATCATCGAATGGACCCG (SEQ ID NO: 440) 435 HGL6.972 ATGGACTCGAATGTAATAATCATTGAACGGAATCGAATGGAATCATCATCGGAT GGAAACGAATGGAATCATCATCGAATGGAATCGAATGGGATC (SEQ ID NO: 441) 436 HGL6.974 GAATGGAATCAACATCAAACGGAATCAAACGGAATTATCGAATGGAATCGAAGA GAATCATCGAATGGCCACGAATGGAATCATCTAATGGAATGGAATGGAATAATC CATGG (SEQ ID NO: 442) 437 HGL6.975 GAAATGGAATGGAAAGGAATAAAATCAAGTGAAATTGGATGGAATGGATTGGA ATGGATTGGAATG (SEQ ID NO: 443) 438 HGL6.978 AAACGGAAAAAAAACGGAATTATCGAATGGAATCGAAGAGAATCATCGAACGA ACCAGAATGGAATCATCTAATGGAATGGAATGGAATAATCCATGG (SEQ ID NO:  444) 439 HGL6.981 ATTAACCCGAATAGAATGGAATGGAATGGAATGGAACGGAACGGAATGGAATG GAATGGAATGGAATGGAATGGATCG (SEQ ID NO: 445) 440 HGL6.982 GCAAAACACAAACAACGCCATAAAAAACTGGGCAAAGGATATGAACAGACATT TTTCAAAACAAAACATACTTATGGCCAAC (SEQ ID NO: 446) 441 HGL6.984 AACATCAAACGGAAAAAAACGGAATTATCGTATGGAATCGAAGAGAATCATCGA ATGGACC (SEQ ID NO: 447) 442 HGL6.985 AAATCAATAAATG TAATTCAGCATATAAACAGAACCAAAGACAAAAACCACAT GATTATCTCAATAGATGCAGAAAAGGCCTTT (SEQ ID NO: 448) 443 HGL6.986 AGAATCAAATGGAATTGAATCGAATGGAATCGAATGGATTGGAAAGGAATAGA ATGGAATGGAATGGAATG (SEQ ID NO: 449) 444 HGL6.988 GAATAGAATTGAATCATCATTGAATGGAATCGAGTAGAATCATTGAAATCGAAT GGAATCATCATCGAATGGAATTGGGTGGAATC (SEQ ID NO: 450) 445 HGL6.989 CACCGAATAGAATCGAATGGAACAATCATCGAATGGACTCAAATGGAATTATCC TCAAATGGAATCGAATGGAATTATCGAATGCAATCGAATAGAATCATCGAATAG ACTCGAATGGAATCATCGAATGGAATGGAATGGAACAGTC (SEQ ID NO: 451) 446 HGL6.992 HGL6.1286 AAATCATCATCGAATGGAATCGAATGGTATCATTGAATGGAATCGAATGGAATC ATCATCAGATGGAAATGAATGGAATCGTCAT (SEQ ID NO: 452) 447 HGL6.997 GAATGGAATCGAAAGGAATAGAATGGAATGGATCGTTATGGAAAGACATCGAAT GGAATGGAATTGACTCGAATGGAATGGACTGGAATGGAACG (SEQ ID NO: 453) 448 HGL6.998 GAATAGAATTGAATCATCATTGAATGGAATCGAGTAGAATCATTGAAATCGAAT GGAATCATCATCGAATGGAATTGGGTGGAATC (SEQ ID NO: 454) 449 HGL6.1001 GAAAGGAATAGAATGGAATGGATCGTTATGGAAAGACATCGAATGGGATGGAA TTGACTCGAATGGATTGGACTGGAATGGAACGGACTCGAATGGAATGGACTGGA ATG (SEQ ID NO: 455) 450 HGL6.1003 TGGATTTCAGATATTTAACACAAAATAGTCAAAGCAGATAAATACTAGCAACTT ATTTTTAATGGGTAACATCATATGTTCGTGCCTT (SEQ ID NO: 456) 451 HGL6.1004 ACAGCAGAAAACGAACATCAGAAAATCACTCTACATGATGCTTAAATACAGAGG GCAAGCAACCCAAGAGAAAACACCACTTCCTAAT (SEQ ID NO: 457) 452 HGL6.1011 AACATACACAAATCAATAAACGTAATCCAGCTTATAAACAGAACCAAAGACAAA AACCACATGATTATCTCAATAGATGCGGAAAAGGCC (SEQ ID NO: 458) 453 HGL6.1012 ACATCAAACGGAATCAAACGGAATTATCGAATGGAATCGAAAAGAATCATCGAA CGGACTCGAATGGAATCATCTAATGGAATGGAATGGAAG (SEQ ID NO: 459) 454 HGL6.1013 ATCGAATGGAATCAACATCAAACGGAAAAAAACGGAATTATCAAATGGAATCGA AGAGAATCATCGAATGGACC (SEQ ID NO: 460) 455 HGL6.1014 GAATAATCATTGAACGGAATCGAATGGAAACATCATCGAATGGAAACGAATGGA ATCATCATCGAATGGAAATGAAAGGAGTCATC (SEQ ID NO: 461) 456 HGL6.1015 CATCAAACGGAATCAAACGGAATTATCGAATGGAATCGAAAAGAATCATCGAAC GGACTCGAATGGAATCATCTAATGGAATGGAATGGAAGAATCCATGGACTCGAA TG (SEQ ID NO: 462) 457 HGL6.1016 TCCAGTCGATCATCATATAGTCAGCACTTATCATACACCAAGCCGTGTGCAAGGA AAGGGAATACAACCATGAACATGATAGATGGATGGTT (SEQ ID NO: 463) 458 HGL6.1017 ACAAACCACTGCTCAAGGAAATAAGGACACAAACAAATGGAACAACATTCCGTG CTCATGGATAGGAAGAATCAATATCGTGAAAATGGCCATACT (SEQ ID NO: 464) 459 HGL6.1019 ACAAAATTGATAGACCACTAGCAAGACTAATAAAGAAGAAAAGAGAGAAGAAT CATTACCATTCAGGACATAGGCATGGGCAAGGAC (SEQ ID NO: 465) 460 HGL6.1024 AAACGGAATCAAACGGAATTATCGAATGGAATCGAAGAGAATCATCGAATGGAC TCGAATGGAATCATCTAATGGAATGGAATGGAAGAATCCATGG (SEQ ID NO: 466) 461 HGL6.1026 ATACAC AAATCAATAAATG TAATCCAGCATATAAACAGAACCAAAGACAAAAA CCATATGATTATCTCAATGGATGCAGAAAAGGCC (SEQ ID NO: 467) 462 HGL6.1027 AATNGAATAGAATCATCGAATGGACTCGAATGGAATCATCGANNNTANTGATGG AACAGTC (SEQ ID NO: 468) 463 HGL6.1030 TGGAATGGAATCATCGCATAGAATCGAATGGAATTACCATCGAATGGGATCGAA TGGTATCAACATCAAACGCAAAAAAACGGAATTATCGAATGGAATCGAAGAGAA TCTTCGAACGGACCCG (SEQ ID NO: 469) 464 HGL6.1031 GAATTGAATTGAATGGAATGGAATGCAATGGAATCTAATGAAACGGAAAGGAA AGGAATGGAATGGAATGGAATG (SEQ ID NO: 470) 465 HGL6.1033 AACAGAATGGAATCAAATCGAATGAAATGGAATGGAATAGAAAGGAATGGAAT GAAATGGAATGGAAAGGATTCGAATGGAATGCAATCG (SEQ ID NO: 471) 466 HGL6.1034 ATGGAATGGAATGGAATGGAATTAAATGGAATGGAAAGGAATGGAATCGAATG GAAAGGAATC (SEQ ID NO: 472) 467 HGL6.1037 HGL6.1245 GTCGAAATGAATAGAATGCAATCATCATCAAATGGAATCCAATGGAATCATCAT CAAATAGAATCGAATGGAATCATCAAATGGAATCGAATGGAGTCATTG (SEQ ID NO: 473) 468 HGL6.1039 TGGAATTATCGAAAGCAAACGAATAGAATCATCGAATGGACTCGAATGGAATCA TCGAATGGAATGGAATGGAACAG (SEQ ID NO: 474) 469 HGL6.1045 AAAGGAATGGAATGCAATGGAATGCAATGGAATGCACAGGAATGGAATGGAAT GGAATGGAAAGGAATG (SEQ ID NO: 475) 470 HGL6.1046 AATCTAATGGAATCAACATCNAACGGAAAAAAACGGAATTATCGAATGGAATCN AAGAGAATCATCNAATGGACC (SEQ ID NO: 476) 471 HGL6.1047 TACACAACAAAAGAAATACTCAACACAGTAAACAGACAACCTTCAGAACAGGA GAAAATATTTGCAAATACATCTAACAAAGGGCTAATATCCAGAATCT (SEQ ID NO: 477) 472 HGL6.1048 NGCAATCNTAGTNTCAGATAAAACAGACATTAAACCAACAAAGATCAAAAGAG ACAAAGAAGGCCANTAC (SEQ ID NO: 478) 473 HGL6.1052 GAATCGAATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATC NAAAAGAATCATCNAATGGACC (SEQ ID NO: 479) 474 HGL6.1055 ACAGTTAACAAAAACCGAACAATCTAATTACGAAATGAACAAAAGATATGAACA GACATTTCACCCGAGAGTATACAGGGGCCAGGCATGGT (SEQ ID NO: 480) 475 HGL6.1056 AATGGAATCGAATGGAATGCAATCCAATGGAATGGAATGCAATGCAATGGAATG GAATCGAACGGAATGCAGTGGAAGGGAATGG (SEQ ID NO: 481) 476 HGL6.1057 GAACACAGAAAAATTTCAAAGGAATAATCAACAGGGATTGATAACTAACTGGAT TTAGAGAGCCAAGGCAAAGAGAATCAAAGCACAGGGCCTGAGTCGGAG (SEQ ID NO: 482) 477 HGL6.1058 TATACCACACAAATGCAAAAGATTATTAGCAACAATTATCAACAGCAATATGTC AACAAGTTGACAAACCTAGAGGACATGGAT (SEQ ID NO: 483) 478 HGL6.1061 CACCATGAGTCATTAGGTAAATGCAAATCAAAACCACAATGAAATACTTCACAC CCATGAAGATGGCTATAATAAAAAAACAGACA (SEQ ID NO: 484) 479 HGL6.1067 AGTTGAATAGAACCAATCCGAATGAAATGGAATGGAATGGAACGGAATGGAATT GAATGGAATGGAATGGAATGCAATGGA (SEQ ID NO: 485) 480 HGL6.1069 AAGTAATAAGACTGAATTAGTAATACAAAGTGTCTCAACAAAGAAAATTGCGGG ACTGTTCATGCTCATGGACAGGAAGAATCAATATCATGAAAATGGCC (SEQ ID NO: 486) 481 HGL6.1070 AACTCGATTGCAATGGAATGTAATGTAATGGAATGGAATGGAATTAACGCGAAT AGAATGGAATGGAATGTAATGGAACGGAATGGAATG (SEQ ID NO: 487) 482 HGL6.1074 AAGCGGAATAGAATTGAATCATCATTGAATGGAATCGAGTAGAATCATTGAAAT CGAATGGAATCATAGAATGGAATCCAAT (SEQ ID NO: 488) 483 HGL6.1076 AAAGGAAAACTACAAAACACTGCTGAAAGAAATCATTGACAACACAAACAAAT GGAAACACATCCCAAGATCATGGGTGGGTGGAATCAAT (SEQ ID NO: 489) 484 HGL6.1077 AATGGAATCNAAAGGAATAGAATGGAATGGATCGTTATGGAAAGATATCGAATG GAATGGAATTGACTCGAATGGAATGGACTGGAATGGAACG (SEQ ID NO: 490) 485 HGL6.1078 TAACGGAATAATCATCGAACAGAATCAAATGGAATCATCATTGAATGGAATTGA ATGGAATCTTCGAATAGACATGAATGGACCATCATCG (SEQ ID NO: 491) 486 HGL6.1084 AAAGACCGAAACAACAACAGAAACAGAAACAAACAACAATAAGAAAAAATGTT AAGCAAAACAAATGATTGCACAACTTACATGATTACTGAGTGTTCTAATGGT (SEQ ID NO: 492) 487 HGL6.1085 AAGATTTAAACATAAGACCTAAAACGACAAAAATCCTAGGAGAAAACCTAAGCA ATACCATTCAGGACATAGGCATGGGCAAAGACTTCATG (SEQ ID NO: 493) 488 HGL6.1090 AGAAACAGCCAGAAAACAATTATTACCTACAGCATTAAAACTATTCAAATGACA GCATATTTTTCAGCAGAAATCATGAAGGCCAGAAGGACGTGTCAT (SEQ ID NO: 494) 489 HGL6.1092 ATGTACAC AAATCAATAAATG CAGTCCAGCATATAAACAGAACCAAACACAAA AACCACATGATTATCTCAATAGATGCAGAAAAGGCCTTT (SEQ ID NO: 495) 490 HGL6.1093 AGCAACTTCAGCAAAGTCTCAGGACACAAAATCAATGTGCAAAAATCACAAGCA TTCTTATACACCAATAACAGACAAACAGAGAGCC (SEQ ID NO: 496) 491 HGL6.1094 TTGAATCGAATGGAATCGAATGGATTGGAAAGGAATAGAATGGAATGGAATGGA ATTGACTCAAATGGAATG (SEQ ID NO: 497) 492 HGL6.1097 HGL6.1241 AACGGAATCAAACGGAATTATCGAATGGAATCGAATAGAATCATCGAACGGACT CGAATGGAATCATCTAATGGAATGGAATGGAAG (SEQ ID NO: 498) 493 HGL6.1098 AACATCACTGATCATTAGAAACACACAAATCAAAACCACAATAAGATACCATCT AACACCAGTCACAATGGCTATT (SEQ ID NO: 499) 494 HGL6.1100 TAAGCAATTTCAGCAGTCTCAGGATACAAAATCAATGTGCAAAAATCACAAGCA TTCTTATACACCAACAACAGACAAACAGAGAGCCAAATCG (SEQ ID NO: 500) 495 HGL6.1101 AGAAAAAAACAAACAGCCCATTAAAAGGTAGACAAAGGACATGAACACTTTTCA AAAGAAGACATACATGTGGCCAAACAGCATG (SEQ ID NO: 501) 496 HGL6.1103 ATTGGAATGGAACGGAACAGAACGGAATGGAATGGAATAGAATGGAATGGAAT GGAATGGTATGGAATGGAATGGAATGGTACG (SEQ ID NO: 502) 497 HGL6.1104 AGAGCATCCACAAGGCCCAATTCAAAGAATCTGAAATAATGTATTGTTACTGCA ACAGTTGTGAGTACCAGTGGCATCAG (SEQ ID NO: 503) 498 HGL6.1107 AATCCACAAAGACAACAGAAGAAAAGACAACAGTAGACAAGGATGTCAACCAC ATTTTGGAAGAGACAAGTAATCAAACACATGGCA (SEQ ID NO: 504) 499 HGL6.1109 AAACAGAACCACAGATATCTGTAAAGGATTACACTATAGTATTCAACAGAGTAT GGAACAGAGTATAGTATTCAACAGAGTATGCAAAGAAACTAAGGCCAGAAAG (SEQ ID NO: 505) 500 HGL6.1110 AGCAAACAAACAAACAAACAAACAAACTATGACAGGAACAAAACGTCACATAT CAACATTAACAAAGAATGTAAACAGCCTAAATGCTTCACTTAAAAGTTATAGAC AGGGGCTGGGCATGGTGGCTCACGCC (SEQ ID NO: 506) 501 HGL6.1111 AAAAGTACAGAAGACAACAAAAAATGAGAGAGAGAAAGATAACAGACTATAGC AGCATTGGTGATCAGAGCCACCAG (SEQ ID NO: 507) 502 HGL6.1114 TACAAGAAAATCACAGTAACATTTATAAAACACAGAAGTGTGAACACACAGCTA TTGACCTTGAAAACAGTGAAAGAGGGTCAGCTGTAGAACTAAGACATAAGCAAA GTTTTTCAATCAAGAATACATGGGTGGCC (SEQ ID NO: 508) 503 HGL6.1116 GAATCGAATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATC GAAAAGAATCATCGAACGGACTCGAATGGAATCATCTAATGGAATGGAATGGAA GAATCCATGG (SEQ ID NO: 509) 504 HGL6.1117 AATGGAATCGAATGGAATCATCATCAAATGGAATCTAATGGAATCATTGAACGG AATTGGATGGAATCGTCAT (SEQ ID NO: 510) 505 HGL6.1118 AACGGAATCAAACGGAATTATCGAATGGAATCGAAGAGAATCATCGAATGGCCA CGAATGGAATCATCTAATGGAATGGAATGGAATAATCCATGGACCCGAATG (SEQ ID NO: 511) 506 HGL6.1121 CAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATCGAAGAGAATCATC GAATGGACC (SEQ ID NO: 512) 507 HGL6.1122 CACAACCAAAGCAATGAAAGAAAAGCACAGACTTATTGAAATGAAAGTACACA CCACAGAATGGGAGCAGGCTCAAGCAAGC (SEQ ID NO: 513) 508 HGL6.1123 HGL6.1229 ATCAAAGGGAATCAAGCGGAATTATCGAATGGAATCGAAGAGAATCATCGAATG GACTCGAATGGAATCATGTGATGGAATGGAATGGAATAATCCACGGACT (SEQ ID NO: 514) 509 HGL6.1125 AAGAAACAATCAAAAGGAAGTGCTAGAAATAAAACACACTGTAATAGAAAAGA AGAATGCCTTATGGGCTTATCAATAGACTAGACATGGCCAGG (SEQ ID NO: 515) 510 HGL6.1127 AGATAAGAATAAGGCAAACATAGTAATAGGGAGTTCATGAATAACACACGGAA AGAGAACTTACAGGGCTGTGATCAGGAAACG (SEQ ID NO: 516) 511 HGL6.1128 GGAATCGAATGGAATCAATATCAAACGGAGAAAAACGGAATTATCGAATGGAAT CGAAGAGAATCATCGAATGGACC (SEQ ID NO: 517) 512 HGL6.1130 TCAGACCATAGCAGATAACATGCACATTAGCAATACGATTGCCATGACAGAGTG GTTGGTG (SEQ ID NO: 518) 513 HGL6.1132 AGGAATGGACACGAACGGAATGCAATCGAATGGAATGGAATCTAATAGAAAGG AATTGAATGAAATGGACTGG (SEQ ID NO: 519) 514 HGL6.1133 GGAAGGGAATCAAATGCAACAGAATGTAATGGAATGGAATGCAATGGAATGCA ATGGAATGGAATGGAATGCAATGGAATGG (SEQ ID NO: 520) 515 HGL6.1138 AAATTGGATTGAATCGAATCGAATGGAAAAAATGAAATCAAATGAAATTGAATG GAATCGAAATGAATGTAAACAATGGAATCCAATGGAATCCAATGGAATCGAATC AAATGGTTTTGAGTGGCGTAAAATG (SEQ ID NO: 521) 516 HGL6.1139 AAGGATTCGAATGGAATGCAATCGAATGGAATGGAATCGAACGGAATGGAATA AAATGGAAGAAAACTGGCAAGAAATGGAATCG (SEQ ID NO: 522) 517 HGL6.1141 GAAAAATCATTGAACGGAATCGAATGGAATCATCATCGGATGGAAACGAATGGA ATCATCATCGAATGGAAATGAAAGGAGTCATC (SEQ ID NO: 523) 518 HGL6.1147 GGTTCAACTTACAATATTTTGACTTGACAACAGTGCAAAAGCAATACACGATTAG TAGAAACACACTTCCAATGCCCATAGGACCATTCTGC (SEQ ID NO: 524) 519 HGL6.1150 GGAATCGAATGGAATCAACATCAAACGGAGAAAAACGGAATTATCGAATGGAA TCGAAGAGAATCATCGAATGGACC (SEQ ID NO: 525) 520 HGL6.1152 TAACCTGATTTGCCATAATCCACGATACGCTTACAACAGTGATATACAAGTTACA TGAGAAACACAAACATTTTGCAAGGAAACTGTGGCCAGATG (SEQ ID NO: 526) 521 HGL6.1153 TAACTACTCACAGAACTCAACAAAACACTATACATGCATTTACCAGTTTATTATA AAGATACAAGTCAGGAACAGCCAAATGGAAGAAATGTAAATGGCAAG (SEQ ID NO: 527) 522 HGL6.1155 GCTCAAAGAAATCAGAAATGACACAAGCAAATGGAAAAACATGCCATGTTCATG AATATGAAGAATCAATATTGTTAAAATGGCCATACTGCTCA (SEQ ID NO: 528) 523 HGL6.1157 AAAGAAATGTCACTGCGTATACACACACACGCACATACACACACCATGGAATAC TACTCAGCTATACAAAGGAATGAAATAATCCACAGCCAC (SEQ ID NO: 529) 524 HGL6.1159 GAATAGAACAGAATGGAATCAAATCGAATGAAATGGAATGGAATAGAAAGGAA TGGAATGAAATGGAATGGAAAGGATTCGAATGGAATG (SEQ ID NO: 530) 525 HGL6.1162 TGAACGGAATCGAATGGAATCATCATCGGATGGAAACGAATGGAATCATCATCG AATGGAAATGAAAGGAGTCATC (SEQ ID NO: 531) 526 HGL6.1165 GAATAGAACGAAATGGAATGGAATGGAATGGAATGGAAAGGAATGGAATGGAA TGGAACG (SEQ ID NO: 532) 527 HGL6.1166 AACGTGACATACATACAAAAAGTTTTTAGAGCAAGTGAAATTTTAGCTGCTATAT GTTAATTGGTGGTAATCCC (SEQ ID NO: 533) 528 HGL6.1169 GGAATAACAACAACAACAACCAAAAGACATATAGAAAACAAACAGCACGATGG CAGATGTAAAGCCTACC (SEQ ID NO: 534) 529 HGL6.1174 GACAAAAAGAATCATCATCGAATAGAATCAAATGGAATCTTTGAATGGACTCAA AAGGAATATCGTCAAATGGAATCAAAAGCCATCATCGAATGGACTGAAATGGAA TTATCAAATGGACTCG (SEQ ID NO: 535) 530 HGL6.1175 GTAACAAAACAGACTCATAGACCAATAGAACAGAATAGAGAATTCAGAAATAA GACTGCACTTCTATGACCATGTGATCTTAGACAAACCT (SEQ ID NO: 536) 531 HGL6.1176 AGATAAAAAGAACAGCAGCCAAAATGACAAAAGCAAAAAGCAAAATCGTGTTA GAGCCAGGTGTGGTGATGTGTGCT (SEQ ID NO: 537) 532 HGL6.1178 GCAATCTCAGGATACAAAATCAATGTGCAAAAATCACAAGCATTCTCATACACC AATAACAGACAAACAGAGCCAAATCATG (SEQ ID NO: 538) 533 HGL6.1179 AACCAAACCAAGCAAACAAACAAACAGTAAAAACTCAATAACAACCAACAAAC AGGAAATACCAGGTAATTCAGATTATCTAGTTATGTGCCATAGT (SEQ ID NO: 539) 534 HGL6.1181 GAATGAATTGAATGCAAACATCGAATGGTCTCGAATGGAATCATCTTCAAATGG AATGGAATGGAATCATCGCATAGAATCGAATGGAATTATCAACGAATGGAATCG AATGGAATCATCATCAGATGGAAATGAATGGAATCGTCAT (SEQ ID NO: 540) 535 HGL6.1183 TGGAATGGAATCAAATCGCATGGAATCGAATGGAATAGAAAAGAATCAAACAG AGTGGAATGGAATGGAATGGAATGGAATCATGCCGAATGGAATG (SEQ ID NO: 541) 536 HGL6.1184 GAATCCATGTTCATAGCACAACAACCAAACAGAAGAAATCACTGTGAAATAAGA AACAAAGCAAAACACAGATGTCGACACATGGCA (SEQ ID NO: 542) 537 HGL6.1185 AAATGGAATAATGAAATGGAATCGAACGGAATCATCATCAAAAGGAACCGAAT GAAGTCATTGAATGGAATCAAAGGCAATCATGGTCGAATGGAATCAAATGGAAA CAGCATTGAATAGAATTGAATGGAGTCATCACATGGAATCG (SEQ ID NO: 543) 538 HGL6.1186 GAATTAACCCGAATAGAATGGAATGGAATGGAATGGAACAGAACGGAACGGAA TGGAATGGAATGGAATGGAATGGAATG (SEQ ID NO: 544) 539 HGL6.1188 AAGATATACAAGCAGCCAACAAACATACGAAAGAATGCTCAACATCACTAATCC TCAGAGAAATTTAAATCAAAACCACAATGAGTTACAATCTCATACCAGTCAGAA T (SEQ ID NO: 545) 540 HGL6.1190 AGAATTACAAACCACTGCTCAACAAAATAAAAGAGTACACAAACAAATGGAAG AATATTCCATGCTTATGGATAGGAAGAATCAATATTGTGAAAATGGCCATACT (SEQ ID NO: 546) 541 HGL6.1192 CATCGAATGGACTCGAATGGAATAATCATTGAACGGAATCGAAGGGAATCATCA TCGGATGGAAACGAATGGAATCATCATCGAATGGAAATG (SEQ ID NO: 547) 542 HGL6.1194 CACCCATCTGTAGGACCAGGAAGCCTGATGTGGGAGAGAACAGCAGGCTAAATC CAGGGTTGGTCTCTACAGCAGAGGGAATCACAAGCCTGTTAGCAAGTGAAGAAC CAACACTGGCAAGAGTGTGAAGGCC (SEQ ID NO: 548) 543 HGL6.1195 TAATGCAAACTAAAACGACAATGAGATATCAATACATAACTACCAGAAAGGCTA ACAAAAAAACAGTCATAACACACCAAAGGCTGATGAGTGAGGATGTGCAG (SEQ ID NO: 549) 544 HGL6.1196 AAAGGAATCAAACGGAATTATCGAATGGAATCGAAAAGAATCATCGAACGGACT CGAATGGAATCATCTAATGGAATGGAATGGAAGAATCCATGGACTCGAATG (SEQ ID NO: 550) 545 HGL6.1198 AGCAACTTCAGCAAAGTCTCAGGATACAAAATCAATGAGCAAAAATCACAAGCA TTCTTACACACCAATAACAGACAAACAGAGAGCC (SEQ ID NO: 551) 546 HGL6.1199 GGATATAAACAAGAAAACAACTAATCACAACTCAATATCAAAGTGCAATGATGG TGCAAAATGCAAGTATGGTGGGGACAGAGAAAGGATGC (SEQ ID NO: 552) 547 HGL6.1200 AATCAGTAAACGTAATACAGCATATAAACAGAACCAAAGACAAAAACCACATG ATTATCTCAATAGATGCAGAAAAGGCC (SEQ ID NO: 553) 548 HGL6.1202 AACATCAAACGGAAAAAAACGGAAATATCGAATGGAATCGAAGAGAATCATCG AATGGACC (SEQ ID NO: 554) 549 HGL6.1203 TAAAATGGAATCGAATGGAATCAACATCAAATGGAATCAAATGGAATCATTGAA CGGAATTGAATGGAATCGTCAT (SEQ ID NO: 555) 550 HGL6.1204 AATCATCATCGAATGGAATCGAATGGTATCATTGAATGGAATCGAATGGAATCA TCATCAGATGGAAATGAATGGAATCGTCAT (SEQ ID NO: 556) 551 HGL6.1205 CAATGCGTCAAGCTCAGACGTGCCTCACTACGGCAATGCGTCAAGCTCAGGCGT GCCTCACTAT (SEQ ID NO: 557) 552 HGL6.1206 AAGACAGAACACTGAAACTCAACAGAGAAGTAACAAGAACACCTAAGACAAGG AAGGAGAGGGAAGGCAGGCAG (SEQ ID NO: 558) 553 HGL6.1209 TAAGCTGATAAGCAACTTTAGCAAAGTCTCAGGATACAAAATCAATGTACAAAA ATCACAAGCATTCTTATACACCAACAACAGACAGACGGAGAGCCAAA (SEQ ID NO: 559) 554 HGL6.1212 ATGAACACGAATGTAATGCAATCCAATAGAATGGAATCGAATGGCATGGAATAT AAAGAAATGGAATCGAAGAGAATGGAAACAAATGGAATGGAATTGAATGGAAT GGAATTG (SEQ ID NO: 560) 555 HGL6.1216 AACAATCACTAGTCCTTAAGTAAGAGACAACACCTTTTGTCACACACAGTTTGTC CTAACTTTATCTTGGTAATTGGGGAGACC (SEQ ID NO: 561) 556 HGL6.1217 TAATGAGAAGACACAGACAACACAAAGAATCACAGAAACATGACACAGGTGAC AAGAACAGGCAAGGACCTGCAGTGCACAGGAGCC (SEQ ID NO: 562) 557 HGL6.1218 TGTTGAGAGAAATTAAACAAAGCACAGATAAATGGAAAAACGTGTTCATAGATT GAAAGACTTCATGTTGTATGGTGTC (SEQ ID NO: 563) 558 HGL6.1219 ATCAAACGGAATCAAACGGAATTATCGAATGGAATCGAAGAGAATCATCGAACG GACTCGAATGGAATCATCTAATGGAATGGGATGG (SEQ ID NO: 564) 559 HGL6.1222 ACACAACAACCAAGAAACAACCCCATTAAGAAGTGGGAAAAATACATGAATAA ACACATCTCAAAAGAAGACAAACAAGTGGCTAAC (SEQ ID NO: 565) 560 HGL6.1225 AATGGAAAGGAATCAAATGGAATATAATGGAATGCAATGGACTCGAATGGAATG GAATGGAATGGACCCAAATGGAATGGAATGGAATGGAATG (SEQ ID NO: 566) 561 HGL6.1226 GGAATACAACGGAATGGAATCGAAAAAAATGGAAAGGAATGAAATGAATGGAA TGGAATGGAATGGAATGGATGGGAATGGAATGGAATGG (SEQ ID NO: 567) 562 HGL6.1227 GAATCAAGCGGAATTATCGAATGGAATCGAAGAGAATCATCGAAAGGACTCGAA TGGAATCATCTAATGGAATGGAATGGAATAATACACGGACC (SEQ ID NO: 568) 563 HGL6.1232 AACAACAACAACAACAGGAAAACAACCTCAGTATGAAGACAAGTACATTGATTT ATTCAACATTTACTGATCACTTTTCAGGTGGTAGGCAGACC (SEQ ID NO: 569) 564 HGL6.1233 AAGATAACCTGTGCCCAGGAGAAAAACAATCAATGGCAACAAAAGCAGAAACA ACACAAATGATACAATTAGCAGACAGAAACATTGAGATTGCTATT (SEQ ID NO: 570) 565 HGL6.1234 AATGGACTCCAATGGAATAATCATTGAACGGAATCNAATGGAATCATCATCGGA TGGAAATGANTGGAATCNTCNTCNAATGGAATCN (SEQ ID NO: 571) 566 HGL6.1237 ANNCNNTAAACGTAATCCATCACATAAACANGANCNAANAGNNNAACCGCNNG ATTATCTCNNNNNNTGCNNAAAAGGCC (SEQ ID NO: 572) 567 HGL6.1240 HGL6.1277 TAATTGATTCGAAATTAATGGAATTGAATGGAATGCAATCAAATGGAATGGAAT GTAATGCAATGGAATGTAATAGAATGGAAAGCAATGGAATG (SEQ ID NO: 573) 568 HGL6.1242 AAAGGAATGGACTTGAACAAAATGAAATCGAACGATAGGAATCGTACAGAACG GAAAGAAATGGAACGGAATGGAATG (SEQ ID NO: 574) 569 HGL6.1243 AGCAACTTCAGCAAAATCTCAGGATACAAAATCAATGTACAAAAATCACAAGCA TTCTTATACACCAACAACAGACAAACAGAGAGCC (SEQ ID NO: 575) 570 HGL6.1247 TGAGCAGGGAACAATGCGGATAAATTTCACAAATACAATGTTGAGCAAAAGAAA GACACAAAANAATACACACATACACACCATATGGGCTAGG (SEQ ID NO: 576) 571 HGL6.1254 AATGGAATGGAATGTACAAGAAAGGAATGGAATGAAACCGAATGGAATGGAAT GGACGCAAAATGAATGGAATGGAAGTCAATGG (SEQ ID NO: 577) 572 HGL6.1260 AAGTTCAAACATCAGTATTAACCTTGAACATCAATGGCCTACATGCATCACTTAA AACATACAGACAGGCAAATTGGGTTAAGAAAACAAACAAGCAAACAAAACATG TTCCAAACATTTGTTGGCTAT (SEQ ID NO: 578) 573 HGL6.1262 GGAATAATCATTGAACGGAATCGAATGGAATCATCATCGGATGGAAACGAATGG AATCATCATCGAATGGAAATGAAAGGAGTCATC (SEQ ID NO: 579) 574 HGL6.1264 GGAACGAAATCGAATGGAACGGAATAGAATAGACTCGAATGTAATGGATTGCTA TGTAATTGATTCGAATGGAATGGAATCG (SEQ ID NO: 580) 575 HGL6.1265 TGAAAGGAATAGACTGGAACAAAATGAAATCGAATGGTAGGAATCATACAGAA CAGAAAGAAATGGAACGGAATGGAATG (SEQ ID NO: 581) 576 HGL6.1266 AACCCGAATAGAATGGAATGGAATGGAATGGAACGGAACGGAATGGAATGGAA TGGATTGGAATGGAATGGAATG (SEQ ID NO: 582) 577 HGL6.1267 AAAGAGAATCAAATGGAATTGAATCGAATGGAATCGAATGGATTGGAAAGGAA TAGAATGGAATGGAATGGAATGGAATGGAATGGAATG (SEQ ID NO: 583) 578 HGL6.1269 AAAACACACAAACATACATGTGGATGCACATATAAACATGCACATACACACACA CATAAATGCACAAACACACTTAACACAAGCACACATGCAAACAAACACATGG (SEQ ID NO: 584) 579 HGL6.1270 AATGGAATCATCAGTAATGGAATGGAAAGGAATGGAAAGGACTGGAATGGAAT GGAATGGAATGGAATGG (SEQ ID NO: 585) 580 HGL6.1271 GGAACAAAATGAAATCGAACGGTAGGAATCGTACAGAACGGAAAGAAATGGAA CGGAATGGAATGCACTCAAATGGAAAGGAGTCCAATGGAATCGAAAGGAATAG AATGGAATGG (SEQ ID NO: 586) 581 HGL6.1272 AGAATGAGATCAAGCAGTATAATAAAGGAAGAAGTAGCAAAATTACAACAGAG CAGTGAAATGGATATGCTTTCTGGCAATAATTGTGAAAGGTCTGGTAATGAGAA AGTAGCAACAGCTAGTGGCTGCCAC (SEQ ID NO: 587) 582 HGL6.1273 AACAAATGGAATCAACATCGAATGGAATCGAATGGAAACACCATCGAATTGAAA CGAATGGAATTATCATGAAATTGAAATGGATGGACTCATCATCG (SEQ ID NO: 588) 583 HGL6.1278 TAACATGCAGCATGCACACACGAATACACAACACACAAACATGTATGCACGCAC ACGTGAATACACAACACACACAAACATGCATGCATGCATACATGAATACACAGC ACACAAATATCCAGCAT (SEQ ID NO: 589) 584 HGL6.1279 GAATGGAATCAACATCAAACGGAAAAAAAACGGAATTATCGAATGGAATCGAA TAGAATCATCGAATGGACC (SEQ ID NO: 590) 585 HGL6.1281 AATCGAATGAAATGGAGTCAAAAGGAATGGAATCGAATGGCAAGAAATCGAAT GTAATGGAATCGCAAGGAATTGATGTGAACGGAACGGAATGGAAT (SEQ ID NO: 591) 586 HGL6.1282 AATGGAATTGAACGGAAACATCAGCGAATGGAATCGAAAGGAATCATCATGGA ATAGATTCGAATGGAATGGAAAGGAATGGAATGGAATG (SEQ ID NO: 592) 587 HGL6.1283 ATGGAATCAACATCAAACAGAATCAAACGGAATTATCGAATGGAATCGAAGACA ATCATCGAATGGACTCGAATGGAATCATCTAATGGAATGGAATGGAAGAATCCA TGGTCTCGAATGCAATCATCATCG (SEQ ID NO: 593) 588 HGL6.1284 GAATAATCATTGAACGGAATCGAATGGAATCATCTTCGGATGGAAACGAATGGA ATCATCATCGAATGGAAATGAAAGGAGTCATC (SEQ ID NO: 594) 589 HGL6.1288 AATGGACTCGAATGGAATAATCATTGAACGGAATCGAATGGAATCATCATCGGA TGGAAATGAGTGGAATCATCATCGAATGGAATCG (SEQ ID NO: 595) 590 HGL6.1290 AAATGAAATCGAACGGTAGGAATCGTACAGAACGGAAAGAAATGGAACGGAAT GGAATGCAATCGAATGGAAAGGAGTCCAATGGAAGGGAATCGAAT (SEQ ID NO: 596) 591 HGL6.1291 TACCAAACATTTAAAGAACAAATATCAATCCTACGCAAACCATTCTGAAACACA GAGATGGAGGATATACAGCGAAACTCATTCTACATGGCC (SEQ ID NO: 597) 592 HGL6.1292 TATTGGAATGGAATGGAATGGAGTCGAATGGAACGGAATGCACTCGAATGGAAG GCAATGCAATGGAATGCACTCAACAGGAATAGAATGGAATGGAATGGAATGG (SEQ ID NO: 598) 593 HGL6.1294 AGAGAGTATTCATCATGAGGAGTATTACTGGACAAATAATTCACAAACGAACAA ACCAAAGCGATCATCTTTGTACTGGCTGGCTA (SEQ ID NO: 599) 594 HGL6.1295 GGAATTTAATAGAATGTACCCGAATGGAACGGAATGGAATGGAATTGTATGGCA TGGAATGGAA (SEQ ID NO: 600) 595 HGL6.1298 GCAATCCANTANAATGGAATCGAATGGCATGGAATATAAAGAAATGGAATCGAA GAGAATGGAGACAAATGGAATGGAATTGAATGGAATGGAATTG (SEQ ID NO: 601) 596 HGL6.1299 AATGGAATCGAATGGAATCATCATCAAATGGAATCTAATGGAATCATTGAACGG AATTAAATGGAATCGTCATCGAATGAATTCAATGCAATCAACGAATGGTCTCGA ATGGAACCAC (SEQ ID NO: 602) 597 HGL6.1300 AATTGCAAAAGAAACACACATATACACATATAAAACTCAAGAAAGACAAAACTA ACCTATGGTGATAGAAATCAGAAAAGTACAGTACATTGGTTGTCTTGGTGGG (SEQ ID NO: 603) 598 HGL6.1303 TGACATCATTATTATCAAGAAACATTCTTACCACTGTTACCAACTTCCCAACACA GACTATGGAGAGAGAGATAAGACAGAATAGCATT (SEQ ID NO: 604) 599 HGL6.1305 GGAATCTATAATACAGCTGTTTATAGCCAAGCACTAAATCATATGATACAGAAA ACAAATGCAGATGGTTTGAAGGGTGGG (SEQ ID NO: 605) 600 HGL6.1308 AAAGAATTGAATTGAATAGAATCACCAATGAATTGAATCGAATGGAATCGTCAT CGAATGGAATCGAAGGGAATCATTGGATGGGCTCA (SEQ ID NO: 606) 601 HGL6.1311 ATCATCGAATGGAATCGAATGGAATCAATATCAAACGGAAAAAAACGGAATTAT CGAATGGAATCGAATAGAATCATCGAATGGACC (SEQ ID NO: 607) 602 HGL6.1314 GAATGAAATCGTATAGAATCATCGAATGCAACTGAATGGAATCATTAAATGGAC TTGAAAGGAATTATTATGGAATGGAATTG (SEQ ID NO: 608) 603 HGL6.1316 TAAGCAACTTCAGCAAAGTCTCAGGATACAAAATCAATGTGCAAAAATCTCAAG CATTCTTATACACGAACAACAGACAAACAGAGAGCT (SEQ ID NO: 609) 604 HGL6.1317 ACTCAAAAGGAATTGATTCGAATGGAATAGAATGGCAAGGAATAGTATTGAATT GAATGGAATGGAATGGACCCAAATG (SEQ ID NO: 610) 605 HGL6.1319 GAATGGAATTTAAAGGAATAGAATGGAAGGAATCGGATGGAATGGAATGGAAT AGAATGGAGTCGAATGGAATAGAATCGAATGGAATGGCATTG (SEQ ID NO: 611) 606 HGL6.1323 AACAAAAAATGAGTCAAGCCTTAAATAAAATCAGAGCCAAAAAAGAAGACATT ACATCTGATAAGACAAAAATTCAAAGGACCATC (SEQ ID NO: 612) 607 HGL6.1324 AACCCAGTGGAATTGAATTGAATGGAATTGAATGGAATGGAAAGAATCAATCCG AGTCGAATGGAATGGTATGGAATGGAATGGCATGGAATCAAC (SEQID NO: 613) 608 HGL6.1327 ATCAACATCAAACGGAAAAAAAACGGAATTATCGAATGGAATCGAAGAGAATC ATCGAATGGACC (SEQ ID NO: 614) 609 HGL6.1331 AAGGAATGGAATGGTACGGAATAGAATGGAATGGAACGAATTGTAATGGAATG GAATTTAATGGAACGGAATGGAATGGAATGGAATCAACG (SEQ ID NO: 615) 610 HGL6.1334 AACGGAATGGAAAGCAATTTAATCAAATGCAATACAGTGGAATTGAAGGGAATG GAATGGAATGGC (SEQ ID NO: 616) 611 HGL6.1335 AATCGAATGGAACGGAATAGAATAGACTCGAATGTAATGGATTGCTATGTAATT GATTCGAATGGAATGGAATCGAATGGAATGCAATCCAATGGAATGGAATGCAAT GCAATGGAATGGAATCGAACGGAATGCAGTGGAAGGGAATGG (SEQ ID NO: 617) 612 HGL6.1336 TAGCAACATTTTAGTAACATGATAGAAACAAAACAGCAACATAGCAATGCAATA GTAACACAACAGCAACATCATAACATGGCAGCA (SEQ ID NO: 618) 613 HGL6.1337 GGACAAATTGCTAGAAATAAACAAATTACCAAAAATGATTCAAGTAGAGACAGA GAATCAAAATAGAACTACACATAAGTGGGCCAAG (SEQ ID NO: 619) 614 HGL6.1340 AAAATAGAATGAAAGAGAATCAAATGGAATTGAATCGAATGGAATCGAATGGA TTGGAAAGGAATAGAATGGAATGGAATGGAATG (SEQ ID NO: 620) 615 HGL6.1342 AGCAAACAAGTGAATAAACAAGCAAACAAGTGAACAAGCAAACAAGTGAATAA ACAAGCAAACAAGTGAACAAGCAAACAAGTGAATAAACAAGCAAACAAGTGAA CAAGGAAACAAGTGAATAAACAAAGGCTCT (SEQ ID NO: 621) 616 HGL6.1346 AATGGAATCAACACGAGTGCAATTGAATGGAATCGAATGGAATGGAATGGAATG GAATGAATTCAACCCGAATGGAATGGAAAGGAATGGAATC (SEQ ID NO: 622) 617 HGL6.1347 AATATACGC AAATCAATAAATG TAATCCAGCATATAAACAGTACTAAAGACAAA AACCACATGATTATCTCAATAGATGCAGAAAAGGCC (SEQ ID NO: 623) 618 HGL6.1352 GAATCGAATGGAATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATC GAAGAGNNNNNNCGAATGGACC (SEQ ID NO: 624) 619 HGL6.1354 AACACGAATGTAATGCAATCCAATAGAATGGAATCGAATGGCATGGAATATAAA GAAATGGAATCGAAGAGAATGGAAACAAACGGAATGGAATTGAATGGAATGGA ATTGAATGGAATGGGAACGAATGGAGTGAAATTG (SEQ ID NO: 625) 620 HGL6.1355 GAATGGAACGGAATAGAACAGACTCGAATGTAATGGATTGCTATGTAATTGATT CGAATGGAATGGAATCGAATGGAATGCAATCCAATGGAATGGAATGCAATGCAA TGGAATGGAATCGAATGGAATGCAGTGGAAGGGAATGG (SEQ ID NO: 626) 621 HGL6.1356 GAATCGAATGGAATCAATATCAAACGGAAAAAAACGGAATTATCGAATGGAATC GAAGAGAATCATCGAATGGACC (SEQ ID NO: 627) 622 HGL6.1359 TAAACAACGAGAACACATGAACACAAAGAGGGGAACAACAGACACCAAGACCT TCTTGAGGGTGGAGGATGGGAGGAGGGAG (SEQ ID NO: 628) 623 HGL6.1360 AGCAACTTCAGCAGTCTCAGTATACAAAAACAATGTGCAAAAATCACAAGCATT CCTATATGCCAATAACAGACAAACAGAGAGCC (SEQ ID NO: 629) 624 HGL6.1361 ATCAAAAGAAAAGCAACCTAACAAATACGGGAAGAATATTTGAATAGACATTTC ACAGGAAAAGATATATGAATGGCCAAAAAGCAAATGAAAAG (SEQ ID NO: 630) 625 HGL6.1364 ATAAACATCAAACGGAATCAAACGGAATTATCGAATGGAATCGAAGAGAATAAT CGAATGGACTCAAATGGAGTCATCTAATGGAATGGTATGGAAGAATCCATGGAC TCCAACGCAATCATCAGCGAATGGAATC (SEQ ID NO: 631) 626 HGL6.1365 AAAAGAAAAGACAAAAGACACCAATTGCCAATACTGAAATGAAAAAACAGGTA ATAACTATTGATCCCATGGACATTAAAATGATGTTGAAGGAACACCAC (SEQ ID NO: 632) 627 HGL6.1368 AGCAATAACCAAACAACCTCATTAAAAAGTAGGCAAAGGACATAAACAGACACT TTTCAAAAGAAGACATACACGTGGCCAACAAACATATG (SEQ ID NO: 633) 628 HGL6.1370 AGCAACTTCAGCAAAGTCTCAGGATACAAAATCGATGTGCAAAAATCACAAGCA TTCTTATACACCAATAACAGGCAAACAGAGAGCC (SEQ ID NO: 634) 629 HGL6.1371 GTCATATTTGGGATTTATCATCTGTTTCTATTGTTGTTGTTTTAGTACACACAAAG CCACAATAAATATTCTAGGCT (SEQ ID NO: 635) 630 HGL6.1373 ATCATCGAATGGAATAGAATGGTATCAACATCAAACGGAGAAAAACGGAATTAT CGAATGGAATCGAAGAGAATCTTCGAACGGACC (SEQ ID NO: 636) 631 HGL6.1374 AAATAAGCCAACGGTCATAAATTGCAAAGCCTTTTACAATCCAAACATGATGGA AACGATATGCCATTTTGAAGGTGATTTGAAAAGCACATGGTTT (SEQ ID NO: 637) 632 HGL6.1375 GAATGGAATCATCGCATAGAATCGGATGGAATTATCATCGAATGGAATCGAATG GTATCAACATCAAACGGAAAAAAACGGAATTATCGAATGGAATCGAATTGAATC ATCGAACGGACCCG (SEQ ID NO: 638) 633 HGL6.1378 AATGGACTCGAATGGAATAATCATTGAACGGAATCGAATGGAATCATCATCGGA TGGAAATGAATGGAATAATCCATGGACTCGAATGCAATCATCATCGAATGGAAT CGAATGGAATCATCGAATGGACTCG (SEQ ID NO: 639) 634 HGL6.1379 AATGCAATCATCAACTGGCTTCGAATGGAATCATCAAGAATGGAATCGAATGGA ATCATCGAATGGACTC (SEQ ID NO: 640) 635 HGL6.1380 AAGAGACCAATAAGGANTANGTAAGCAACANGAGGAAGGAGANANGGGCAAG AGAGATGACCAGAGTT (SEQ ID NO: 641) 636 HGL6.1382 TGGAATCATCATAAAATGGAATCGAATGGAATCAACATCAAATGGAATCAAATG GAATCATTGAACGGAATTGAATGGAATCGTCAT (SEQ ID NO: 642) 637 HGL6.1383 GGAATCATCGCATAGAATCGAATGGAATTATCATCGAATGGAATCGAATGGAAT CAACATCAAACGAAAAAAAACCGGAATTATCGAATGGAATCGAAGAGAATCATC GAACGGACC (SEQ ID NO: 643) 638 HGL6.1384 AAATCATCATCGAATGGGATCGAATGGTATCCTTGAATGGAATCGAATGGAATC ATCATCAGATGGAAATGAATGGAATCGTCAT (SEQ ID NO: 644) 639 HGL6.1386 GGAATGTAATAGAACGGAAAGCAATGGAATGGAACGCACTGGATTCGAGTGCA ATGGAATCTATTGGAATGGAATCGAATGGAATGGTTTGGCATGGAATGGAC (SEQ ID NO: 645)

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We claim:
 1. A nucleic acid library comprising a plurality of linear recombinant double stranded DNA constructs, wherein each double stranded DNA construct comprises (a) a promoter; (b) a heterologous coding region downstream from the promoter, wherein the coding region encodes a detectable polypeptide; (c) a heterologous cross-linking region downstream of the coding region; (d) a heterologous polynucleotide sequence of between 20-500 base pairs in length located downstream of the promoter and upstream of the coding region; and (e) a first PCR primer binding site and a second PCR primer binding site, wherein the first PCR primer binding site is upstream of the polynucleotide sequence and the second PCR primer site is downstream of the polynucleotide sequence; wherein at least 10¹³ different polynucleotide sequences are represented in the plurality of double stranded nucleic acid constructs, and wherein the first PCR primer and the second PCR primer are the same for each construct in the plurality of double stranded nucleic acid constructs.
 2. The nucleic acid library of claim 1, wherein expressed RNA from the cross-linking region can serve as a site for ligation to a linker containing a 3′-puromycin residue.
 3. The nucleic acid library of claim 2, wherein mRNA expressed from the cross linking region is complementary to a DNA linker sequence to be used.
 4. The nucleic acid library of claim 1, wherein the polynucleotide sequence of between 20-500 base pairs are genomic fragments.
 5. The nucleic acid library of claim 1, wherein the polynucleotide sequence of between 20-500 base pairs are synthetic sequences.
 6. The nucleic acid library of claim 1, wherein the polynucleotide sequence is between 20-400 base pairs in length.
 7. The nucleic acid library of claim 1, wherein the library comprises at least 10¹⁴ different polynucleotide sequences.
 8. The nucleic acid library of claim 1, wherein the double stranded nucleic acid constructs further comprise (a) one or more unique restriction sites upstream of the polynucleotide sequence and downstream of the promoter, and (b) one or more unique restriction sites downstream of the polynucleotide sequence.
 9. The nucleic acid library of claim 1, wherein the first (5′) or second (3′) primer binding site is upstream of the coding region in the double stranded nucleic acid construct.
 10. An mRNA pool resulting from transcription of the library of claim
 1. 11. A method for identifying translational enhancing elements (TEEs), comprising (a) contacting the nucleic acid library of claim 1 with reagents for RNA transcription under conditions to promote transcription of RNA from the double stranded nucleic acid constructs, resulting in an RNA expression product; (b) contacting the RNA expression product with reagents for ligating a linker containing a puromycin residue to the 3′ end of the RNA expression product, resulting in a labeled RNA expression product; (c) contacting the labeled RNA expression product with reagents for protein expression under conditions to promote protein translation from the labeled RNA expression product, resulting in a RNA-polypeptide fusion product; (d) isolating RNA-polypeptide fusion products; (e) converting the isolated RNA-polypeptide fusion products to cDNA by reverse transcription-PCR using a primer to the 3′ end of the isolated RNA-polypeptide fusion products; (f) amplifying the cDNA by PCR using primers to the 5′ and 3′ end of the cDNA; and (g) repeating steps (a)-(f) a desired number of times, wherein the amplified polynucleotide sequence fragments comprise TEEs.
 12. The method of claim 11, wherein the primers used in step (f) add a promoter to the 5′ end and a cross-linking region to the 3′ end of the cDNA after each round of selection.
 13. The method of claim 11, wherein the linker comprises a DNA linker complementary to the RNA expression product.
 14. The method of claim 11, wherein the polynucleotide sequences in the library comprise genomic fragments, and wherein a starting pool of library constructs contains at least a five-fold coverage of the genome of interest.
 15. The method of claim 11, wherein the method further comprises testing polynucleotide sequences identified as TEEs for TEE activity in vivo.
 16. An isolated polynucleotide, comprising a nucleic acid sequence according to any one of SEQ ID NOS: 1-5 and 7-645.
 17. The isolated polynucleotide of claim 16, wherein the polynucleotide is selected from the group consisting of SEQ ID NO:1-5, 448, 495, 623, 408, 12, 54, 401, 553, 434, 458, 214, 327, 397, 471, 398, 301, 310 and
 583. 18. An isolated polynucleotide comprising a nucleic acid sequence according to SEQ ID NO:1.
 19. The isolated polynucleotide of claim 18, comprising a nucleic acid sequence according to SEQ ID NO:2.
 20. The isolated polynucleotide of claim 18, comprising a nucleic acid sequence according to SEQ ID NO:3.
 21. An isolated polynucleotide comprising a nucleic acid sequence according to SEQ ID NO:4.
 22. The isolated polynucleotide of claim 16, wherein the polynucleotide is 200 nucleotides or less in length.
 23. An expression vector comprising (a) a promoter; (b) a heterologous TEE downstream of the promoter, where the TEE comprises a polynucleotide according to claim 16; and (c) a cloning site suitable for cloning of an protein-encoding nucleic acid of interest located upstream of the TEE, and downstream of the promoter.
 24. The expression vector of claim 23, further comprising a protein-encoding nucleic acid cloned into the cloning site.
 25. A recombinant host cell comprising the expression vector of claim
 23. 26. A method for protein expression, comprising contacting the expression vector of claim 24 with reagents and under conditions suitable for promoting expression of the polypeptide encoded by the protein-encoding nucleic acid.
 28. The method of claim 26, wherein the protein expression is carried out in vitro.
 29. The method of claim 26, wherein the protein expression is carried out in a recombinant host cell. 